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Sample records for likes california lithium

  1. California Lithium Battery, Inc. | Department of Energy

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    California Lithium Battery, Inc. America's Next Top Energy Innovator Challenge 626 likes California Lithium Battery, Inc. Argonne National Laboratory California Lithium Battery ("CALBattery") is a start-up California company established in 2011 to develop and manufacture a breakthrough high energy density and long cycle life lithium battery for utility energy storage, transportation, and defense industries. The company is a joint venture between California-based Ionex Energy Storage

  2. California Geothermal Power Plant to Help Meet High Lithium Demand

    Energy.gov [DOE]

    Ever wonder how we get the materials for the advanced batteries that power our cell phones, laptops, and even some electric vehicles? The U.S. Department of Energy's Geothermal Technologies Program (GTP) is working with California's Simbol Materials to develop technologies that extract battery materials like lithium, manganese, and zinc from geothermal brines produced during the geothermal production process.

  3. EERE Success Story-California: Geothermal Plant to Help Meet High Lithium

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    Demand | Department of Energy Geothermal Plant to Help Meet High Lithium Demand EERE Success Story-California: Geothermal Plant to Help Meet High Lithium Demand May 21, 2013 - 5:54pm Addthis Through funding provided by the American Recovery and Reinvestment Act of 2009, EERE's Geothermal Technologies Office is working with California's Simbol Materials to develop technologies that extract battery materials like lithium, manganese, and zinc from geothermal brines. Simbol has the potential to

  4. California: Geothermal Plant to Help Meet High Lithium Demand...

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    Geothermal Plant to Help Meet High Lithium Demand California: Geothermal Plant to Help Meet High Lithium Demand May 21, 2013 - 5:54pm Addthis Through funding provided by the...

  5. California Geothermal Power Plant to Help Meet High Lithium Demand...

    Energy.gov [DOE] (indexed site)

    phones, laptops, and even some electric vehicles? The U.S. Department of Energy's Geothermal Technologies Program (GTP) is working with California's Simbol Materials to develop...

  6. American Lithium Energy Corp | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Lithium Energy Corp Jump to: navigation, search Name: American Lithium Energy Corp Place: San Marcos, California Zip: 92069 Product: California-based developer of lithium ion...

  7. Ultrathin Li3VO4 Nanoribbon/Graphene Sandwich-Like Nanostructures with Ultrahigh Lithium ion Storage Properties

    SciTech Connect

    Lu, Pei-Jun; Liu, Jun N.; Liang, Shuquan; Liu, Jun; Wang, W. J.; Lei, Ming; Tang, Shasha; Yang, Qian

    2015-03-01

    Two-dimensional (2D) "graphene-like" inorganic materials, because of the short lithium ion diffusion path and unique 2D carrier pathways, become a new research focus of the lithium storages. Some "graphene-like" binary compounds, such as, MnO2, MoS2 and VO2 ultrathin nanosheets, have been synthesized by a peeling method, which also exhibit enhanced lithium storage performances. However, it still remains a great challenge to synthesize widely-used lithium-containing ternary oxides with "graphene-like" nanostructures, because the lithium-containing ternary oxides, unlike ternary layered double hydroxides (LDH), are very hard to be directly peeled. Herein, we successfully synthesized ultrathin Li3VO4 nanoribbons with a thickness of about 3 nm by transformation from ultrathin V2O5•xH2O nanoribbons, moreover, we achieved the preparation of ultrathin Li3VO4 nanoribbon@graphene sandwich-like nanostructures (LVO/G) through a layer-by-layer assembly method. The unique sandwich-like nanostructures shows not only a high specific reversible capacitance (up to 452.5 mA h•g-1 after 200 cycles) but also an excellent cycling performance (with more than 299.2 mA h•g-1 of the capacity at 10 C after 1000 cycles) as well as very high rate capability. Such template strategy, using "graphene-like" binary inorganic nanosheets as templates to synthesize lithium-containing ternary oxide nanosheets, may be extended to prepare other ternary oxides with "graphene-like" nanostructures

  8. Expanded North Carolina Lithium Facility Opens, Boosting U.S...

    Office of Environmental Management (EM)

    ... A Material Change: Bringing Lithium Production Back to America California Geothermal Power Plant to Help Meet High Lithium Demand Low-temp geothermal technologies are meeting a ...

  9. Clean Anodic Lithium Films for Longer Life, Rechargeable Lithium...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Energy Storage Energy Storage Find More Like This Return to Search Clean Anodic Lithium ... polymer electrolytes are used to prepare clean anodic lithium films for use in safe, ...

  10. Thin-Film Lithium-Based Electrochromic Devices - Energy Innovation...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Find More Like This Return to Search Thin-Film Lithium-Based Electrochromic Devices ... For lithium-based electrochromic cells, the electrolyte contains mobile lithium which ...

  11. Lithium battery

    SciTech Connect

    Ikeda, H.; Nakaido, S.; Narukara, S.

    1983-08-16

    In a lithium battery having a negative electrode formed with lithium as active material and the positive electrode formed with manganese dioxide, carbon fluoride or the like as the active material, the discharge capacity of the negative electrode is made smaller than the discharge capacity of the positive electrode, whereby a drop in the battery voltage during the final discharge stage is steepened, and prevents a device using such a lithium battery as a power supply from operating in an unstable manner, thereby improving the reliability of such device.

  12. Combustion synthesized rod-like nanostructure hematite with enhanced lithium storage properties

    SciTech Connect

    Xiong, Q.Q.; Shi, S.J.; Tang, H.; Wang, X.L.; Gu, C.D.; Tu, J.P.

    2015-01-15

    Graphical abstract: Fe{sub 2}O{sub 3} nanorods are synthesized by combustion method using alcohol as both solvent and fuel. As an anode material for lithium-ion batteries, the Fe{sub 2}O{sub 3} nanorod electrode delivers good electrochemical performance. - Highlights: • We prepared Fe{sub 2}O{sub 3} nanorod by a facile and powerful combustion method. • The Fe{sub 2}O{sub 3} nanorod shows high capacity, good cycle stability, and rate performance. • Combustion saves time and energy to meet the demand of green and sustainable industry. - Abstract: Fe{sub 2}O{sub 3} nanorods are synthesized by combustion method using alcohol as both solvent and fuel, which is a facile and effective strategy for the large-scale and inexpensive fabrication. The Fe{sub 2}O{sub 3} nanorods are with the well distributed diameters of 20–30 nm and length ranging from 80 to 100 nm. As an anode material for lithium-ion batteries, the Fe{sub 2}O{sub 3} nanorod electrode delivers a high discharge capacity of 761.7 mA h g{sup −1} after 60 cycles at 500 mA g{sup −1}, and 727.2 mA h g{sup −1} at a high current density of 2000 mA g{sup −1}. The good electrochemical performance is attributed to the sufficient contact of active material and electrolyte, large surface area, and short diffusion length of Li{sup +}.

  13. Lithium Ion Conducting Ionic Electrolytes - Energy Innovation...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Energy Storage Energy Storage Find More Like This Return to Search Lithium Ion Conducting ... electrolytes which combine lithium salts with high molecular weight anionic polymers. ...

  14. Polymeric Ionic Networks with High Charge Density: Solid-like Electrolytes in Lithium Metal Batteries

    DOE PAGES [OSTI]

    Zhang, Pengfei; Li, Mingtao; Jiang, Xueguang; Fang, Youxing; Veith, Gabriel M.; Sun, Xiao-Guang; Dai, Sheng

    2015-11-02

    Polymerized ionic networks (PINs) with six ion pairs per repeating unit are synthesized by nucleophilic-substitution-mediated polymerization or radical polymerization of monomers bearing six 1-vinylimidazolium cations. PIN-based solid-like electrolytes show good ionic conductivities (up to 5.32 × 10-3 S cm-1 at 22 °C), wide electrochemical stability windows (up to 5.6 V), and good interfacial compatibility with the electrodes.

  15. Polymeric Ionic Networks with High Charge Density: Solid-like Electrolytes in Lithium Metal Batteries

    SciTech Connect

    Zhang, Pengfei; Li, Mingtao; Jiang, Xueguang; Fang, Youxing; Veith, Gabriel M.; Sun, Xiao-Guang; Dai, Sheng

    2015-11-02

    Polymerized ionic networks (PINs) with six ion pairs per repeating unit are synthesized by nucleophilic-substitution-mediated polymerization or radical polymerization of monomers bearing six 1-vinylimidazolium cations. PIN-based solid-like electrolytes show good ionic conductivities (up to 5.32 × 10-3 S cm-1 at 22 °C), wide electrochemical stability windows (up to 5.6 V), and good interfacial compatibility with the electrodes.

  16. Lithium Salt-doped, Gelled Polymer Electrolyte with a Nanoporous...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Find More Like This Return to Search Lithium Salt-doped, Gelled Polymer Electrolyte with a ... electrolyte material for use in lithium ion batteries that exhibits better ion ...

  17. Lithium Batteries

    Office of Scientific and Technical Information (OSTI)

    Thin-Film Battery with Lithium Anode Courtesy of Oak Ridge National Laboratory, Materials Science and Technology Division Lithium Batteries Resources with Additional Information...

  18. California - Compare - U.S. Energy Information Administration (EIA)

    Energy Information Administration (EIA) (indexed site)

    California California

  19. California - Rankings - U.S. Energy Information Administration (EIA)

    Energy Information Administration (EIA) (indexed site)

    California California

  20. California - Search - U.S. Energy Information Administration (EIA)

    Energy Information Administration (EIA) (indexed site)

    California California

  1. Manufacturing of Protected Lithium Electrodes for Advanced Lithium-Air, Lithium-Water & Lithium-Sulfur Batteries

    SciTech Connect

    Visco, Steven J

    2015-11-30

    The global demand for rechargeable batteries is large and growing rapidly. Assuming the adoption of electric vehicles continues to increase, the need for smaller, lighter, and less expensive batteries will become even more pressing. In this vein, PolyPlus Battery Company has developed ultra-light high performance batteries based on its proprietary protected lithium electrode (PLE) technology. The Company’s Lithium-Air and Lithium-Seawater batteries have already demonstrated world record performance (verified by third party testing), and we are developing advanced lithium-sulfur batteries which have the potential deliver high performance at low cost. In this program PolyPlus Battery Company teamed with Corning Incorporated to transition the PLE technology from bench top fabrication using manual tooling to a pre- commercial semi-automated pilot line. At the inception of this program PolyPlus worked with a Tier 1 battery manufacturing engineering firm to design and build the first-of-its-kind pilot line for PLE production. The pilot line was shipped and installed in Berkeley, California several months after the start of the program. PolyPlus spent the next two years working with and optimizing the pilot line and now produces all of its PLEs on this line. The optimization process successfully increased the yield, throughput, and quality of PLEs produced on the pilot line. The Corning team focused on fabrication and scale-up of the ceramic membranes that are key to the PLE technology. PolyPlus next demonstrated that it could take Corning membranes through the pilot line process to produce state-of-the-art protected lithium electrodes. In the latter part of the program the Corning team developed alternative membranes targeted for the large rechargeable battery market. PolyPlus is now in discussions with several potential customers for its advanced PLE-enabled batteries, and is building relationships and infrastructure for the transition into manufacturing. It is likely

  2. San Marcos, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    district.12 Registered Energy Companies in San Marcos, California American Lithium Energy Corp References US Census Bureau Incorporated place and minor civil...

  3. EERE Success Story-California: Geothermal Plant to Help Meet...

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    Bridging the Gap: Helping Small Businesses With Big Ideas Develop New Industries California Geothermal Power Plant to Help Meet High Lithium Demand Project Overview Positive Impact ...

  4. Lithium Batteries

    Office of Scientific and Technical Information (OSTI)

    information about thin-film lithium batteries is available in full-text and on the Web. ... Additional Web Pages: Thin Films for Advanced Batteries Thin-Film Rechargeable Lithium, ...

  5. Lithium battery

    SciTech Connect

    Koch, V. R.

    1981-02-24

    An electrolyte for a rechargeable electrochemical cell featuring diethylether, a cosolvent, and a lithium salt is disclosed.

  6. Hydrogen, lithium, and lithium hydride production

    SciTech Connect

    Brown, Sam W; Spencer, Larry S; Phillips, Michael R; Powell, G. Louis; Campbell, Peggy J

    2014-03-25

    A method of producing high purity lithium metal is provided, where gaseous-phase lithium metal is extracted from lithium hydride and condensed to form solid high purity lithium metal. The high purity lithium metal may be hydrided to provide high purity lithium hydride.

  7. Advanced Lithium Ion Battery Technologies - Energy Innovation...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Find More Like This Return to Search Advanced Lithium Ion Battery Technologies Lawrence ... improved battery life when used in the fabrication of negative silicon electrodes. ...

  8. Solid-state Inorganic Lithium-Ion Conductors - Energy Innovation...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Find More Like This Return to Search Solid-state Inorganic Lithium-Ion Conductors ... milling system for preparation of electrodes for use in a solid state lithium-ion battery. ...

  9. Nanostructured Anodes for Lithium-Ion Batteries - Energy Innovation...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Advanced Materials Find More Like This Return to Search Nanostructured Anodes for Lithium-Ion Batteries New Anodes for Lithium-ion Batteries Increase Energy Density Four-Fold...

  10. Lithium literature review: lithium's properties and interactions...

    Office of Scientific and Technical Information (OSTI)

    Lithium may be used as a breeding blanket and reactor coolant in these facilities. Physical and chemical properties of lithium as well as the chemical interactions of lithium with ...

  11. Lithium uptake data of lithium imprinted polymers

    SciTech Connect

    Susanna Ventura

    2015-12-04

    Batch tests of lithium imprinted polymers of variable composition to assess their ability to extract lithium from synthetic brines at T=45C. Initial selectivity data are included

  12. California | National Nuclear Security Administration

    National Nuclear Security Administration (NNSA)

    California Hard work pays off at 2016 Sandia California Intern Symposium The summer internship season recently culminated at the 2016 Intern Symposium at Sandia National Laboratories California. The symposium was an all-day event that showcased intern projects and offered students the chance to network with the rest of the Sandia community. "Internships like... Sandia California hosts Military Academic Collaboration students Sandia National Laboratories in California was one of nine

  13. Lithium ion conducting electrolytes

    DOEpatents

    Angell, C. Austen; Liu, Changle

    1996-01-01

    A liquid, predominantly lithium-conducting, ionic electrolyte having exceptionally high conductivity at temperatures of 100.degree. C. or lower, including room temperature, and comprising the lithium salts selected from the group consisting of the thiocyanate, iodide, bromide, chloride, perchlorate, acetate, tetrafluoroborate, perfluoromethane sulfonate, perfluoromethane sulfonamide, tetrahaloaluminate, and heptahaloaluminate salts of lithium, with or without a magnesium-salt selected from the group consisting of the perchlorate and acetate salts of magnesium. Certain of the latter embodiments may also contain molecular additives from the group of acetonitrile (CH.sub.3 CN) succinnonitrile (CH.sub.2 CN).sub.2, and tetraglyme (CH.sub.3 --O--CH.sub.2 --CH.sub.2 --O--).sub.2 (or like solvents) solvated to a Mg.sup.+2 cation to lower the freezing point of the electrolyte below room temperature. Other particularly useful embodiments contain up to about 40, but preferably not more than about 25, mol percent of a long chain polyether polymer dissolved in the lithium salts to provide an elastic or rubbery solid electrolyte of high ambient temperature conductivity and exceptional 100.degree. C. conductivity. Another embodiment contains up to about but not more than 10 mol percent of a molecular solvent such as acetone.

  14. Lithium ion conducting electrolytes

    DOEpatents

    Angell, C.A.; Liu, C.

    1996-04-09

    A liquid, predominantly lithium-conducting, ionic electrolyte is described having exceptionally high conductivity at temperatures of 100 C or lower, including room temperature, and comprising the lithium salts selected from the group consisting of the thiocyanate, iodide, bromide, chloride, perchlorate, acetate, tetrafluoroborate, perfluoromethane sulfonate, perfluoromethane sulfonamide, tetrahaloaluminate, and heptahaloaluminate salts of lithium, with or without a magnesium-salt selected from the group consisting of the perchlorate and acetate salts of magnesium. Certain of the latter embodiments may also contain molecular additives from the group of acetonitrile (CH{sub 3}CN), succinnonitrile (CH{sub 2}CN){sub 2}, and tetraglyme (CH{sub 3}--O--CH{sub 2}--CH{sub 2}--O--){sub 2} (or like solvents) solvated to a Mg{sup +2} cation to lower the freezing point of the electrolyte below room temperature. Other particularly useful embodiments contain up to about 40, but preferably not more than about 25, mol percent of a long chain polyether polymer dissolved in the lithium salts to provide an elastic or rubbery solid electrolyte of high ambient temperature conductivity and exceptional 100 C conductivity. Another embodiment contains up to about but not more than 10 mol percent of a molecular solvent such as acetone. 2 figs.

  15. Southern California Edison Company Smart Grid Demonstration Project...

    OpenEI (Open Energy Information) [EERE & EIA]

    is based in Rosemead, California. Overview Deploy and evaluate an 8 MW utility-scale lithium-ion battery technology to improve grid performance and aid in the integration of wind...

  16. lithium cobalt oxide cathode

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    lithium cobalt oxide cathode - Sandia Energy Energy Search Icon Sandia Home Locations ... SunShot Grand Challenge: Regional Test Centers lithium cobalt oxide cathode Home...

  17. Solid Lithium Ion Conducting Electrolytes Suitable for Manufacturing...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Oak Ridge National Laboratory Contact ORNL About This Technology Technology Marketing SummaryThe lithium ion battery found in electronics like cell phones uses liquid electrolytes ...

  18. Electrochromic nickel oxide simultaneously doped with lithium...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    More Like This Return to Search Electrochromic nickel oxide simultaneously doped with lithium and a metal dopant United States Patent Patent Number: 8,687,261 Issued: April 1,...

  19. Lithium Iron Phosphate Composites for Lithium Batteries (IN-11...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Lithium Iron Phosphate Composites for Lithium Batteries (IN-11-024) Low-Cost Phosphate Compounds Enhance Lithium Battery Performance Argonne National Laboratory Contact ANL About ...

  20. Lithium Balance | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Balance Jump to: navigation, search Name: Lithium Balance Place: Copenhagen, Denmark Product: Lithium ion battery developer. References: Lithium Balance1 This article is a stub....

  1. Spatial periphery of lithium isotopes

    SciTech Connect

    Galanina, L. I. Zelenskaja, N. S.

    2013-12-15

    The spatial structure of lithium isotopes is studied with the aid of the charge-exchange and (t, p) reactions on lithium nuclei. It is shown that an excited isobaric-analog state of {sup 6}Li (0{sup +}, 3.56MeV) has a halo structure formed by a proton and a neutron, that, in the {sup 9}Li nucleus, there is virtually no neutron halo, and that {sup 11}Li is a Borromean nucleus formed by a {sup 9}Li core and a two-neutron halo manifesting itself in cigar-like and dineutron configurations.

  2. Lithium metal oxide electrodes for lithium cells and batteries...

    Office of Scientific and Technical Information (OSTI)

    Title: Lithium metal oxide electrodes for lithium cells and batteries A lithium metal oxide positive electrode for a non-aqueous lithium cell is disclosed. The cell is prepared in ...

  3. Sacramento County, California: Energy Resources | Open Energy...

    OpenEI (Open Energy Information) [EERE & EIA]

    Florin, California Folsom, California Foothill Farms, California Galt, California Gold River, California Isleton, California La Riviera, California North Highlands,...

  4. Molten salt lithium cells

    DOEpatents

    Raistrick, Ian D.; Poris, Jaime; Huggins, Robert A.

    1982-02-09

    Lithium-based cells are promising for applications such as electric vehicles and load-leveling for power plants since lithium is very electropositive and light weight. One type of lithium-based cell utilizes a molten salt electrolyte and is operated in the temperature range of about 400.degree.-500.degree. C. Such high temperature operation accelerates corrosion problems and a substantial amount of energy is lost through heat transfer. The present invention provides an electrochemical cell (10) which may be operated at temperatures between about 100.degree.-170.degree. C. Cell (10) comprises an electrolyte (16), which preferably includes lithium nitrate, and a lithium or lithium alloy electrode (12).

  5. Molten salt lithium cells

    DOEpatents

    Raistrick, Ian D.; Poris, Jaime; Huggins, Robert A.

    1983-01-01

    Lithium-based cells are promising for applications such as electric vehicles and load-leveling for power plants since lithium is very electropositive and light weight. One type of lithium-based cell utilizes a molten salt electrolyte and is operated in the temperature range of about 400.degree.-500.degree. C. Such high temperature operation accelerates corrosion problems and a substantial amount of energy is lost through heat transfer. The present invention provides an electrochemical cell (10) which may be operated at temperatures between about 100.degree.-170.degree. C. Cell (10) comprises an electrolyte (16), which preferably includes lithium nitrate, and a lithium or lithium alloy electrode (12).

  6. Molten salt lithium cells

    DOEpatents

    Raistrick, I.D.; Poris, J.; Huggins, R.A.

    1980-07-18

    Lithium-based cells are promising for applications such as electric vehicles and load-leveling for power plants since lithium is very electropositive and light weight. One type of lithium-based cell utilizes a molten salt electrolyte and is operated in the temperature range of about 400 to 500/sup 0/C. Such high temperature operation accelerates corrosion problems and a substantial amount of energy is lost through heat transfer. The present invention provides an electrochemical cell which may be operated at temperatures between about 100 to 170/sup 0/C. The cell is comprised of an electrolyte, which preferably includes lithium nitrate, and a lithium or lithium alloy electrode.

  7. Sandia National Laboratories: Locations: Livermore, California

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Livermore, California Livermore, California administration building For more than 50 years, the California campus of Sandia National Laboratories has delivered essential science and technology to resolve the nation's most challenging security issues. Many of these challenges - like energy resources, transportation, immigration, ports, and more - surfaced early in the state of California, providing Sandia/California with a special opportunity to participate in the first wave of solutions to

  8. Lithium-Ion Batteries - Energy Innovation Portal

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Vehicles and Fuels Vehicles and Fuels Energy Storage Energy Storage Energy Analysis Energy Analysis Find More Like This Return to Search Lithium-Ion Batteries Predictive computer models for lithium-ion battery performance under standard and potentially abusive conditions National Renewable Energy Laboratory Contact NREL About This Technology Technology Marketing Summary Design. Build. Test. Break. Repeat. Developing batteries is an expensive and time-intensive process. Testing costs the

  9. Electrical Detector for Liquid Lithium Leaks Around Demountable Pipe Joints

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    | Princeton Plasma Physics Lab Electrical Detector for Liquid Lithium Leaks Around Demountable Pipe Joints This system is designed to detect leaks of liquid lithium from around demountable pipe joints. Demountable pipe joints such as vacuum fittings are likely spots for a leak in any system transporting fluids. Since liquid lithium reacts with air, water, concrete and other common materials, it is important to quickly detect a leak. The system will partially contain the leak and is designed

  10. Solid lithium-ion electrolyte (Patent) | DOEPatents

    Office of Scientific and Technical Information (OSTI)

    uses in lithium batteries, electrochromic devices and other electrochemical applications. ... conductivity; suitable; lithium; batteries; electrochromic; devices; ...

  11. Method of recycling lithium borate to lithium borohydride through diborane

    DOEpatents

    Filby, Evan E.

    1976-01-01

    This invention provides a method for the recycling of lithium borate to lithium borohydride which can be reacted with water to generate hydrogen for utilization as a fuel. The lithium borate by-product of the hydrogen generation reaction is reacted with hydrogen chloride and water to produce boric acid and lithium chloride. The boric acid and lithium chloride are converted to lithium borohydride through a diborane intermediate to complete the recycle scheme.

  12. Effect of additives on lithium cycling efficiency

    SciTech Connect

    Hirai, Toshiro; Yoshimatsu, Isamu; Yamaki, J. )

    1994-09-01

    Lithium cycling efficiency was evaluated for LiAsF[sub 6]-ethylene carbonate/2-methyltetrahydrofuran mixed-solvent electrolyte (LiAsF[sub 6]-EC/2MeTHF) with several additives: tetraalkylammonium chlorides with a long n-alkyl chain and three methyl groups. The ammonium chlorides with n-alkyl group longer than n-C[sub 12]H[sub 25]- increased lithium cycling efficiency. Cetyltrimethylammonium chloride (CTAC) produced the best improvement in lithium cycling efficiency. A figure of merit (FOM) of lithium for 0.01 M CTAC was 46, which was 1.5 times the FOM for the corresponding additive-free electrolyte. The LiAsF[sub 6]-EC/2MeTHF with CTAC showed an increase in FOM with stack pressure, but the effect was less than that for the additive-free LiAsF[sub 6]-EC/2MeTHF. Scanning electron microscope observation showed that the addition of CTAC decreased the needle-like lithium deposition and increased particulate lithium deposition. This deposition morphology may be the main cause of the increase in FOM. The additive had no effect on rate capability for cell cycling at 3 mA/cm[sup 2] discharge and 1 mA/cm[sup 2] charge.

  13. Manufacturing of Protected Lithium Electrodes for Advanced Lithium-Air, Lithium-Water, and Lithium-Sulfur batteries

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    Protected Lithium Electrodes for Advanced Batteries Manufacturing of Protected Lithium Electrodes for Advanced Lithium- Air, Lithium-Water, and Lithium-Sulfur Batteries Developing a Lower Cost and Higher Energy Density Alternative to Lithium- Ion Batteries Introduction As the world moves toward increased electric transportation and the use of renewable sources of energy for grid power, advanced electrochemical energy storage technologies will become more and more important. The introduction of

  14. Lithium Redistribution in Lithium-Metal Batteries

    SciTech Connect

    Ferrese, A; Albertus, P; Christensen, J; Newman, J

    2012-01-01

    A model of a lithium-metal battery with a CoO2 positive electrode has been modeled in order to predict the movement of lithium in the negative electrode along the negative electrode/separator interface during cell cycling. A finite-element approach was used to incorporate an intercalation positive electrode using superposition, electrode tabbing, transport using concentrated solution theory, as well as the net movement of the lithium electrode during cycling. From this model, it has been found that movement of lithium along the negative electrode/separator interface does occur during cycling and is affected by three factors: the cell geometry, the slope of the open-circuit-potential function of the positive electrode, and concentration gradients in both the solid and liquid phases in the cell. (C) 2012 The Electrochemical Society. [DOI: 10.1149/2.027210jes] All rights reserved.

  15. Princeton Plasma Physics Lab - Lithium

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    lithium Nearly everybody knows about lithium - a light, silvery alkali metal - used in rechargeable batteries powering everything from laptops to hybrid cars. What may not be so...

  16. Lithium purification technique

    DOEpatents

    Keough, Robert F.; Meadows, George E.

    1985-01-01

    A method for purifying liquid lithium to remove unwanted quantities of nitrogen or aluminum. The method involves precipitation of aluminum nitride by adding a reagent to the liquid lithium. The reagent will be either nitrogen or aluminum in a quantity adequate to react with the unwanted quantity of the impurity to form insoluble aluminum nitride. The aluminum nitride can be mechanically separated from the molten liquid lithium.

  17. Lithium purification technique

    DOEpatents

    Keough, R.F.; Meadows, G.E.

    1984-01-10

    A method for purifying liquid lithium to remove unwanted quantities of nitrogen or aluminum. The method involves precipitation of aluminum nitride by adding a reagent to the liquid lithium. The reagent will be either nitrogen or aluminum in a quantity adequate to react with the unwanted quantity of the impurity to form insoluble aluminum nitride. The aluminum nitride can be mechanically separated from the molten liquid lithium.

  18. Integrated Dynamic Electron Solutions, Inc. | Department of Energy

    Energy.gov [DOE] (indexed site)

    existing buildings with costs comparable to conventional HVAC. Learn More California Lithium Battery, Inc. Argonne National Laboratory 626 likes California Lithium Battery...

  19. Integrated Dynamic Electron Solutions, Inc. | Department of Energy

    Energy.gov [DOE] (indexed site)

    transport and stationery power plants, marine, cars and trucks. Learn More California Lithium Battery, Inc. Argonne National Laboratory 626 likes California Lithium Battery...

  20. TrakLok Corporation | Department of Energy

    Energy.gov [DOE] (indexed site)

    existing buildings with costs comparable to conventional HVAC. Learn More California Lithium Battery, Inc. Argonne National Laboratory 626 likes California Lithium Battery...

  1. TrakLok Corporation | Department of Energy

    Energy.gov [DOE] (indexed site)

    transport and stationery power plants, marine, cars and trucks. Learn More California Lithium Battery, Inc. Argonne National Laboratory 626 likes California Lithium Battery...

  2. Testing of Liquid Lithium Limiters in CDX-U

    SciTech Connect

    R. Majeski; R. Kaita; M. Boaz; P. Efthimion; T. Gray; B. Jones; D. Hoffman; H. Kugel; J. Menard; T. Munsat; A. Post-Zwicker; V. Soukhanovskii; J. Spaleta; G. Taylor; J. Timberlake; R. Woolley; L. Zakharov; M. Finkenthal; D. Stutman; G. Antar; R. Doerner; S. Luckhardt; R. Seraydarian; R. Maingi; M. Maiorano; S. Smith; D. Rodgers

    2004-07-30

    Part of the development of liquid metals as a first wall or divertor for reactor applications must involve the investigation of plasma-liquid metal interactions in a functioning tokamak. Most of the interest in liquid-metal walls has focused on lithium. Experiments with lithium limiters have now been conducted in the Current Drive Experiment-Upgrade (CDX-U) device at the Princeton Plasma Physics Laboratory. Initial experiments used a liquid-lithium rail limiter (L3) built by the University of California at San Diego. Spectroscopic measurements showed some reduction of impurities in CDX-U plasmas with the L3, compared to discharges with a boron carbide limiter. While no reduction in recycling was observed with the L3, which had a plasma-wet area of approximately 40 cm2, subsequent experiments with a larger area fully toroidal lithium limiter demonstrated significant reductions in both recycling and in impurity levels. Two series of experiments with the toroidal limiter have now be en performed. In each series, the area of exposed, clean lithium was increased, until in the latest experiments the liquid-lithium plasma-facing area was increased to 2000 cm2. Under these conditions, the reduction in recycling required a factor of eight increase in gas fueling in order to maintain the plasma density. The loop voltage required to sustain the plasma current was reduced from 2 V to 0.5 V. This paper summarizes the technical preparations for lithium experiments and the conditioning required to prepare the lithium surface for plasma operations. The mechanical response of the liquid metal to induced currents, especially through contact with the plasma, is discussed. The effect of the lithium-filled toroidal limiter on plasma performance is also briefly described.

  3. Lithium Droplet Injector......Inventors ..--..Lane Roquemore...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Lithium Droplet Injector......Inventors ..--..Lane Roquemore, Daniel Andruczyk A liquid lithium device has been invented that produces spherical droplets of lithium for the control ...

  4. Hierarchically Structured Materials for Lithium Batteries (Journal...

    Office of Scientific and Technical Information (OSTI)

    Hierarchically Structured Materials for Lithium Batteries Citation Details In-Document Search Title: Hierarchically Structured Materials for Lithium Batteries Lithium-ion battery ...

  5. Electrolytic orthoborate salts for lithium batteries (Patent...

    Office of Scientific and Technical Information (OSTI)

    Electrolytic orthoborate salts for lithium batteries Title: Electrolytic orthoborate salts for lithium batteries Orthoborate salts suitable for use as electrolytes in lithium ...

  6. Cathode material for lithium batteries (Patent) | DOEPatents

    Office of Scientific and Technical Information (OSTI)

    Title: Cathode material for lithium batteries A method of manufacture an article of a cathode (positive electrode) material for lithium batteries. The cathode material is a lithium ...

  7. Cathode material for lithium batteries

    DOEpatents

    Park, Sang-Ho; Amine, Khalil

    2013-07-23

    A method of manufacture an article of a cathode (positive electrode) material for lithium batteries. The cathode material is a lithium molybdenum composite transition metal oxide material and is prepared by mixing in a solid state an intermediate molybdenum composite transition metal oxide and a lithium source. The mixture is thermally treated to obtain the lithium molybdenum composite transition metal oxide cathode material.

  8. Cathode material for lithium batteries

    SciTech Connect

    Park, Sang-Ho; Amine, Khalil

    2015-01-13

    A method of manufacture an article of a cathode (positive electrode) material for lithium batteries. The cathode material is a lithium molybdenum composite transition metal oxide material and is prepared by mixing in a solid state an intermediate molybdenum composite transition metal oxide and a lithium source. The mixture is thermally treated to obtain the lithium molybdenum composite transition metal oxide cathode material.

  9. Lithium metal oxide electrodes for lithium batteries

    DOEpatents

    Thackeray, Michael M.; Kim, Jeom-Soo; Johnson, Christopher S.

    2008-01-01

    An uncycled electrode for a non-aqueous lithium electrochemical cell including a lithium metal oxide having the formula Li.sub.(2+2x)/(2+x)M'.sub.2x/(2+x)M.sub.(2-2x)/(2+x)O.sub.2-.delta., in which 0.ltoreq.x<1 and .delta. is less than 0.2, and in which M is a non-lithium metal ion with an average trivalent oxidation state selected from two or more of the first row transition metals or lighter metal elements in the periodic table, and M' is one or more ions with an average tetravalent oxidation state selected from the first and second row transition metal elements and Sn. Methods of preconditioning the electrodes are disclosed as are electrochemical cells and batteries containing the electrodes.

  10. Riverside County, California: Energy Resources | Open Energy...

    OpenEI (Open Energy Information) [EERE & EIA]

    Desert Hot Springs, California East Blythe, California East Hemet, California Glen Avon, California Hemet, California Highgrove, California Home Gardens, California Homeland,...

  11. Tulare County, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Lindsay, California London, California Orosi, California Pixley, California Poplar-Cotton Center, California Porterville, California Richgrove, California Springville,...

  12. Lithium Dendrite Formation

    SciTech Connect

    2015-03-06

    Scientists at the Department of Energy’s Oak Ridge National Laboratory have captured the first real-time nanoscale images of lithium dendrite structures known to degrade lithium-ion batteries. The ORNL team’s electron microscopy could help researchers address long-standing issues related to battery performance and safety. Video shows annular dark-field scanning transmission electron microscopy imaging (ADF STEM) of lithium dendrite nucleation and growth from a glassy carbon working electrode and within a 1.2M LiPF6 EC:DM battery electrolyte.

  13. Lithium metal oxide electrodes for lithium batteries

    DOEpatents

    Thackeray, Michael M.; Johnson, Christopher S.; Amine, Khalil; Kang, Sun-Ho

    2010-06-08

    An uncycled preconditioned electrode for a non-aqueous lithium electrochemical cell including a lithium metal oxide having the formula xLi.sub.2-yH.sub.yO.xM'O.sub.2.(1-x)Li.sub.1-zH.sub.zMO.sub.2 in which 0lithium metal ion with an average trivalent oxidation state selected from two or more of the first row transition metals or lighter metal elements in the periodic table, and M' is one or more ions with an average tetravalent oxidation state selected from the first and second row transition metal elements and Sn. The xLi.sub.2-yH.sub.y.xM'O.sub.2.(1-x)Li.sub.1-zH.sub.zMO.sub.2 material is prepared by preconditioning a precursor lithium metal oxide (i.e., xLi.sub.2M'O.sub.3.(1-x)LiMO.sub.2) with a proton-containing medium with a pH<7.0 containing an inorganic acid. Methods of preparing the electrodes are disclosed, as are electrochemical cells and batteries containing the electrodes.

  14. High Performance Binderless Electrodes for Rechargeable Lithium...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    High Performance Binderless Electrodes for Rechargeable Lithium Batteries National ... Electrode for fast-charging Lithium Ion Batteries, Accelerating Innovation Webinar ...

  15. APPARATUS FOR THE PRODUCTION OF LITHIUM METAL

    DOEpatents

    Baker, P.S.; Duncan, F.R.; Greene, H.B.

    1961-08-22

    Methods and apparatus for the production of high-purity lithium from lithium halides are described. The apparatus is provided for continuously contacting a molten lithium halide with molten barium, thereby forming lithium metal and a barium halide, establishing separate layers of these reaction products and unreacted barium and lithium halide, and continuously withdrawing lithium and barium halide from the reaction zone. (AEC)

  16. Novel Electrolytes for Lithium ...

    Office of Scientific and Technical Information (OSTI)

    Electrolytes for Lithium Ion Batteries Brett L. Lucht Department of Chemistry University of Rhode Island 51 Lower College Rd. Kingston, RI 02881 Tel (401)874-5071 Fax (401) ...

  17. Solid-state lithium battery

    DOEpatents

    Ihlefeld, Jon; Clem, Paul G; Edney, Cynthia; Ingersoll, David; Nagasubramanian, Ganesan; Fenton, Kyle Ross

    2014-11-04

    The present invention is directed to a higher power, thin film lithium-ion electrolyte on a metallic substrate, enabling mass-produced solid-state lithium batteries. High-temperature thermodynamic equilibrium processing enables co-firing of oxides and base metals, providing a means to integrate the crystalline, lithium-stable, fast lithium-ion conductor lanthanum lithium tantalate (La.sub.1/3-xLi.sub.3xTaO.sub.3) directly with a thin metal foil current collector appropriate for a lithium-free solid-state battery.

  18. Lithium formate ion clusters formation during electrospray ionization...

    Office of Scientific and Technical Information (OSTI)

    Biological Sciences Division, Fundamental and Computational Sciences Directorate, Pacific ... LITHIUM; LITHIUM 3; LITHIUM IONS; MASS SPECTROSCOPY; MONOMERS; STABILITY; SYMMETRY Word ...

  19. Review of Reactivity Experiments for Lithium Ternary Alloys

    SciTech Connect

    Jolodosky, A.; Bolind, A.; Fratoni, M.

    2015-09-28

    Lithium is often the preferred choice as breeder and coolant in fusion blankets as it offers high tritium breeding, excellent heat transfer and corrosion properties, and most importantly, it has very high tritium solubility and results in very low levels of tritium permeation throughout the facility infrastructure. However, lithium metal vigorously reacts with air and water and exacerbates plant safety concerns. Consequently, Lawrence Livermore National Laboratory (LLNL) is attempting to develop a lithium-based alloy—most likely a ternary alloy—which maintains the beneficial properties of lithium (e.g. high tritium breeding and solubility) while reducing overall flammability concerns for use in the blanket of an inertial fusion energy (IFE) power plant. The LLNL concept employs inertial confinement fusion (ICF) through the use of lasers aimed at an indirect-driven target composed of deuterium-tritium fuel. The fusion driver/target design implements the same physics currently experimented at the National Ignition Facility (NIF). The plant uses lithium in both the primary coolant and blanket; therefore, lithium related hazards are of primary concern. Reducing chemical reactivity is the primary motivation for the development of new lithium alloys, and it is therefore important to come up with proper ways to conduct experiments that can physically study this phenomenon. This paper will start to explore this area by outlining relevant past experiments conducted with lithium/air reactions and lithium/water reactions. Looking at what was done in the past will then give us a general idea of how we can setup our own experiments to test a variety of lithium alloys.

  20. Lithium battery management system

    DOEpatents

    Dougherty, Thomas J.

    2012-05-08

    Provided is a system for managing a lithium battery system having a plurality of cells. The battery system comprises a variable-resistance element electrically connected to a cell and located proximate a portion of the cell; and a device for determining, utilizing the variable-resistance element, whether the temperature of the cell has exceeded a predetermined threshold. A method of managing the temperature of a lithium battery system is also included.

  1. Conditional Loan Guarantee to Support California Solar Generation Project |

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    Department of Energy Conditional Loan Guarantee to Support California Solar Generation Project Conditional Loan Guarantee to Support California Solar Generation Project April 12, 2011 - 3:08pm Addthis An artist rendering of what the California Valley Solar Ranch project will look like post-construction . | courtesy of SunPower Corporation An artist rendering of what the California Valley Solar Ranch project will look like post-construction . | courtesy of SunPower Corporation Ginny Simmons

  2. Surface-Modified Active Materials for Lithium Ion Battery Electrodes -

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Energy Innovation Portal Energy Storage Energy Storage Advanced Materials Advanced Materials Find More Like This Return to Search Surface-Modified Active Materials for Lithium Ion Battery Electrodes Lawrence Berkeley National Laboratory Contact LBL About This Technology Technology Marketing Summary Berkeley Lab researcher Gao Liu has developed a new fabrication technique for lithium ion battery electrodes that lowers binder cost without sacrificing performance and reliability. Description

  3. Nanotube composite anode materials improve lithium-ion battery performance

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    (ANL-09-034) - Energy Innovation Portal Vehicles and Fuels Vehicles and Fuels Energy Storage Energy Storage Find More Like This Return to Search Nanotube composite anode materials improve lithium-ion battery performance (ANL-09-034) Argonne National Laboratory Contact ANL About This Technology Technology Marketing Summary Rechargeable lithium-ion batteries are a critical technology for many applications, including consumer electronics and electric vehicles. As the demand for hybrid and

  4. CUBICON Materials that Outperform Lithium-Ion Batteries - Energy Innovation

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Portal Advanced Materials Advanced Materials Find More Like This Return to Search CUBICON Materials that Outperform Lithium-Ion Batteries Brookhaven National Laboratory Contact BNL About This Technology Micrograph of CUBICON material. Micrograph of CUBICON material. Technology Marketing Summary The demand for batteries to meet high-power and high-energy system applications has resulted in substantial research and development activities. Lithium-ion batteries are a chief contender today, but

  5. Atmospheric corrosion of lithium electrodes

    SciTech Connect

    Johnson, C.J.

    1981-10-01

    Atmospheric corrosion of lithium during lithium-cell assembly and the dry storage of cells prior to electrolyte fill has been found to initiate lithium corrosion pits and to form corrosion products. Scanning Electron Microscopy (SEM) was used to investigate lithium pitting and the white floccullent corrosion products. Electron Spectroscopy for Chemical Analysis (ESCA) and Auger spectroscopy in combination with X-ray diffraction were used to characterize lithium surfaces. Lithium surfaces with corrosion products were found to be high in carbonate content indicating the presence of lithium carbonate. Lithium electrodes dry stored in unfilled batteries were found to contain high concentration of lithium flouride a possible corrosion product from gaseous materials from the carbon monofluoride cathode. Future investigations of the corrosion phenomena will emphasize the effect of the corrosion products on the electrolyte and ultimate battery performance. The need to protect lithium electrodes from atmospheric exposure is commonly recognized to minimize corrosion induced by reaction with water, oxygen, carbon dioxide or nitrogen (1). Manufacturing facilities customarily limit the relative humidity to less than two percent. Electrodes that have been manufactured for use in lithium cells are typically stored in dry-argon containers. In spite of these precautions, lithium has been found to corrode over a long time period due to residual gases or slow diffusion of the same into storage containers. The purpose of this investigation was to determine the nature of the lithium corrosion.

  6. Lithium | Princeton Plasma Physics Lab

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    reactions also have used lithium to coat the walls of donut-shaped tokamak reactors. ... lithium that may be used to coat components that face the plasma in future tokamaks. ...

  7. Phostech Lithium | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Phostech Lithium Jump to: navigation, search Name: Phostech Lithium Place: St-Bruno-de-Montarville, Quebec, Canada Zip: J3V 6B7 Sector: Hydro Product: String representation...

  8. Marin County, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    California Mill Valley, California Muir Beach, California Novato, California Point Reyes Station, California Ross, California San Anselmo, California San Geronimo, California...

  9. Ventura County, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    California Oak View, California Ojai, California Oxnard, California Piru, California Port Hueneme, California San Buenaventura (Ventura), California Santa Paula, California Simi...

  10. Kern County, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Acres, California Delano, California Derby Acres, California Dustin Acres, California Edwards AFB, California Fellows, California Ford City, California Frazier Park, California...

  11. Thin film method of conducting lithium-ions (Patent) | DOEPatents

    Office of Scientific and Technical Information (OSTI)

    uses in lithium batteries, electrochromic devices and other electrochemical applications. ... conductivity; suitable; lithium; batteries; electrochromic; devices; ...

  12. Lithium disulfide battery

    DOEpatents

    Kaun, Thomas D.

    1988-01-01

    A negative electrode limited secondary electrochemical cell having dense FeS.sub.2 positive electrode operating exclusively on the upper plateau, a Li alloy negative electrode and a suitable lithium-containing electrolyte. The electrolyte preferably is 25 mole percent LiCl, 38 mole percent LiBr and 37 mole percent KBr. The cell may be operated isothermally.

  13. Lithium-cation conductivity and crystal structure of lithium diphosphate

    SciTech Connect

    Voronin, V.I.; Sherstobitova, E.A.; Blatov, V.A.; Shekhtman, G.Sh.

    2014-03-15

    The electrical conductivity of lithium diphosphate Li{sub 4}P{sub 2}O{sub 7} has been measured and jump-like increasing of ionic conductivity at 913 K has been found. The crystal structure of Li{sub 4}P{sub 2}O{sub 7} has been refined using high temperature neutron diffraction at 300–1050 K. At 913 K low temperature triclinic form of Li{sub 4}P{sub 2}O{sub 7} transforms into high temperature monoclinic one, space group P2{sub 1}/n, a=8.8261(4) Å, b=5.2028(4) Å, c=13.3119(2) Å, β=104.372(6)°. The migration maps of Li{sup +} cations based on experimental data implemented into program package TOPOS have been explored. It was found that lithium cations in both low- and high temperature forms of Li{sub 4}P{sub 2}O{sub 7} migrate in three dimensions. Cross sections of the migrations channels extend as the temperature rises, but at the phase transition point have a sharp growth showing a strong “crystal structure – ion conductivity” correlation. -- Graphical abstract: Crystal structure of Li{sub 4}P{sub 2}O{sub 7} at 950 K. Red balls represent oxygen atoms; black lines show Li{sup +} ion migration channels in the layers perpendicular to [001] direction. Highlights: • Structure of Li{sub 4}P{sub 2}O{sub 7} has been refined using high temperature neutron diffraction. • At 913 K triclinic form of Li{sub 4}P{sub 2}O{sub 7} transforms into high temperature monoclinic one. • The migration maps of Li{sup +} implemented into program package TOPOS have been explored. • Cross sections of the migrations channels at the phase transition have a sharp growth.

  14. Lithium Iron Phosphate Composites for Lithium Batteries | Argonne...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Batteries Technology available for licensing: Inexpensive, electrochemically active phosphate compounds with high functionality for high-power and high-energy lithium batteries ...

  15. Experimental lithium system. Final report

    SciTech Connect

    Kolowith, R.; Berg, J.D.; Miller, W.C.

    1985-04-01

    A full-scale mockup of the Fusion Materials Irradiation Test (FMIT) Facility lithium system was built at the Hanford Engineering Development Laboratory (HEDL). This isothermal mockup, called the Experimental Lithium System (ELS), was prototypic of FMIT, excluding the accelerator and dump heat exchanger. This 3.8 m/sup 3/ lithium test loop achieved over 16,000 hours of safe and reliable operation. An extensive test program demonstrated satisfactory performance of the system components, including the HEDL-supplied electromagnetic lithium pump, the lithium jet target, the purification and characterization hardware, as well as the auxiliary argon and vacuum systems. Experience with the test loop provided important information on system operation, performance, and reliability. This report presents a complete overview of the entire Experimental Lithium System test program and also includes a summary of such areas as instrumentation, coolant chemistry, vapor/aerosol transport, and corrosion.

  16. Structural Interactions within Lithium Salt Solvates: Acyclic...

    Office of Scientific and Technical Information (OSTI)

    Structural Interactions within Lithium Salt Solvates: Acyclic Carbonates and Esters Citation Details In-Document Search Title: Structural Interactions within Lithium Salt Solvates: ...

  17. Lithium Energy Japan | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Energy Japan Jump to: navigation, search Name: Lithium Energy Japan Place: Kyoto, Japan Zip: 6018520 Product: Kyoto-based developer, manufacturer and seller of large lithium-ion...

  18. "Radiative Liquid Lithium (metal) Divertor" Inventor..-- Masayuki...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    "Radiative Liquid Lithium (metal) Divertor" Inventor..-- Masayuki Ono The invention utilizes liquid lithium as a radiative material. The radiative process greatly reduces the ...

  19. characterizing lithium-ion electrode microstructures

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    characterizing lithium-ion electrode microstructures - Sandia Energy Energy Search Icon ... SunShot Grand Challenge: Regional Test Centers characterizing lithium-ion electrode ...

  20. Manganese Oxide Composite Electrodes for Lithium Batteries |...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Manganese Oxide Composite Electrodes for Lithium Batteries Technology available for licensing: Improved spinel-containing "layered-layered" lithium metal oxide electrodes Materials ...

  1. Self-Regulating, Nonflamable Rechargeable Lithium Batteries ...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    lithium metal and, in the most serious cases, result in explosive chemical reactions. ... Automatic shutoff mechanism prevents lithium from melting and avoids explosive chemical ...

  2. US Lithium Energetics | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Energetics Jump to: navigation, search Name: US Lithium Energetics Product: Batteries manufacturer References: US Lithium Energetics1 This article is a stub. You can help OpenEI...

  3. Strong Lithium Polysulfide Chemisorption on Electroactive Sites...

    Office of Scientific and Technical Information (OSTI)

    For High-Performance Lithium-Sulfur Battery Cathodes Citation Details In-Document ... For High-Performance Lithium-Sulfur Battery Cathodes Despite the high theoretical ...

  4. Y-12 lithium-6 production

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    lithium-6 production The United States was not expecting the Soviet Union's explosion of their first nuclear device using hydrogen and other fusion materials on August 12, 1953....

  5. San Mateo County, California: Energy Resources | Open Energy...

    OpenEI (Open Energy Information) [EERE & EIA]

    California Daly City, California East Palo Alto, California El Granada, California Emerald Lake Hills, California Foster City, California Half Moon Bay, California...

  6. Sonoma County, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Cotati, California El Verano, California Eldridge, California Fetters Hot Springs-Agua Caliente, California Forestville, California Glen Ellen, California Graton, California...

  7. Solid lithium-ion electrolyte

    DOEpatents

    Zhang, Ji-Guang; Benson, David K.; Tracy, C. Edwin

    1998-01-01

    The present invention relates to the composition of a solid lithium-ion electrolyte based on the Li.sub.2 O--CeO.sub.2 --SiO.sub.2 system having good transparent characteristics and high ion conductivity suitable for uses in lithium batteries, electrochromic devices and other electrochemical applications.

  8. Solid lithium-ion electrolyte

    DOEpatents

    Zhang, J.G.; Benson, D.K.; Tracy, C.E.

    1998-02-10

    The present invention relates to the composition of a solid lithium-ion electrolyte based on the Li{sub 2}O--CeO{sub 2}--SiO{sub 2} system having good transparent characteristics and high ion conductivity suitable for uses in lithium batteries, electrochromic devices and other electrochemical applications. 12 figs.

  9. Novel Lithium Ion Anode Structures: Overview of New DOE BATT...

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    Lithium Ion Anode Structures: Overview of New DOE BATT Anode Projects Novel Lithium Ion ... Nanoscale Heterostructures and Thermoplastic Resin Binders: Novel Lithium-Ion Anodes

  10. Lithium Methyl Carbonate as a Reaction Product of Metallic Lithiumand...

    Office of Scientific and Technical Information (OSTI)

    Lithium methyl carbonate is only one of the components, the others being lithium oxalate and lithium methoxide. Authors: Zhuang, Guorong V. ; Yang, Hui ; Ross Jr., Philip N. ; Xu, ...

  11. Advanced Lithium Power Inc ALP | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Lithium Power Inc ALP Jump to: navigation, search Name: Advanced Lithium Power Inc (ALP) Place: Vancouver, British Columbia, Canada Product: They develop lithium ion and advanced...

  12. Linking Ion Solvation and Lithium Battery Electrolyte Properties...

    Energy.gov [DOE] (indexed site)

    Liquids for Lithium Battery Electrolytes Inexpensive, Nonfluorinated (or Partially Fluorinated) Anions for Lithium Salts and Ionic Liquids for Lithium Battery Electrolytes ...

  13. California: Geothermal Plant to Help Meet High Lithium Demand

    Energy.gov [DOE]

    Using an EERE investment, Simbol Materials is co-producing electric vehicle batteries from co-produced fluids.

  14. California Geothermal Power Plant to Help Meet High Lithium Demand...

    Office of Environmental Management (EM)

    Ever wonder how we get the materials for the advanced batteries that power our cell ... to manufacture its high concentration photovoltaic (HCPV) solar modules and is expected ...

  15. A Lithium-Air Battery Based on Lithium Superoxide | Argonne National...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    A Lithium-Air Battery Based on Lithium Superoxide January 20, 2016 Tweet EmailPrint ... However there have been no reports of a battery based on lithium superoxide (LiO2), ...

  16. California Lighting Technology Center (University of California...

    OpenEI (Open Energy Information) [EERE & EIA]

    gTechnologyCenter(UniversityofCalifornia,Davis)&oldid765625" Feedback Contact needs updating Image needs updating Reference needed Missing content Broken link Other...

  17. Lithium niobate explosion monitor

    DOEpatents

    Bundy, Charles H.; Graham, Robert A.; Kuehn, Stephen F.; Precit, Richard R.; Rogers, Michael S.

    1990-01-01

    Monitoring explosive devices is accomplished with a substantially z-cut lithium niobate crystal in abutment with the explosive device. Upon impact by a shock wave from detonation of the explosive device, the crystal emits a current pulse prior to destruction of the crystal. The current pulse is detected by a current viewing transformer and recorded as a function of time in nanoseconds. In order to self-check the crystal, the crystal has a chromium film resistor deposited thereon which may be heated by a current pulse prior to detonation. This generates a charge which is detected by a charge amplifier.

  18. Lithium niobate explosion monitor

    DOEpatents

    Bundy, C.H.; Graham, R.A.; Kuehn, S.F.; Precit, R.R.; Rogers, M.S.

    1990-01-09

    Monitoring explosive devices is accomplished with a substantially z-cut lithium niobate crystal in abutment with the explosive device. Upon impact by a shock wave from detonation of the explosive device, the crystal emits a current pulse prior to destruction of the crystal. The current pulse is detected by a current viewing transformer and recorded as a function of time in nanoseconds. In order to self-check the crystal, the crystal has a chromium film resistor deposited thereon which may be heated by a current pulse prior to detonation. This generates a charge which is detected by a charge amplifier. 8 figs.

  19. Materials and Processing for Lithium-Ion batteries

    SciTech Connect

    Daniel, Claus

    2008-01-01

    Lithium ion battery technology is projected to be the leapfrog technology for the electrification of the drivetrain and to provide stationary storage solutions to enable the effective use of renewable energy sources. The technology is already in use for low-power applications such as consumer electronics and power tools. Extensive research and development has enhanced the technology to a stage where it seems very likely that safe and reliable lithium ion batteries will soon be on board hybrid electric and electric vehicles and connected to solar cells and windmills. However, safety of the technology is still a concern, service life is not yet sufficient, and costs are too high. This paper summarizes the state of the art of lithium ion battery technology for nonexperts. It lists materials and processing for batteries and summarizes the costs associated with them. This paper should foster an overall understanding of materials and processing and the need to overcome the remaining barriers for a successful market introduction.

  20. Lithium-Air Battery: High Performance Cathodes for Lithium-Air Batteries

    SciTech Connect

    2010-08-01

    BEEST Project: Researchers at Missouri S&T are developing an affordable lithium-air (Li-Air) battery that could enable an EV to travel up to 350 miles on a single charge. Todays EVs run on Li-Ion batteries, which are expensive and suffer from low energy density compared with gasoline. This new Li-Air battery could perform as well as gasoline and store 3 times more energy than current Li-Ion batteries. A Li-Air battery uses an air cathode to breathe oxygen into the battery from the surrounding air, like a human lung. The oxygen and lithium react in the battery to produce electricity. Current Li-Air batteries are limited by the rate at which they can draw oxygen from the air. The team is designing a battery using hierarchical electrode structures to enhance air breathing and effective catalysts to accelerate electricity production.

  1. Method of recycling lithium borate to lithium borohydride through methyl borate

    DOEpatents

    Filby, Evan E.

    1977-01-01

    This invention provides a method for the recycling of lithium borate to lithium borohydride which can be reacted with water to generate hydrogen for utilization as a fuel. The lithium borate by-product of the hydrogen generation reaction is reacted with hydrogen chloride and water to produce boric acid and lithium chloride. The boric acid and lithium chloride are converted to lithium borohydride through a methyl borate intermediate to complete the recycle scheme.

  2. ,"California Natural Gas Summary"

    Energy Information Administration (EIA) (indexed site)

    Prices" "Sourcekey","N3050CA3","N3010CA3","N3020CA3","N3035CA3","N3045CA3" "Date","Natural Gas Citygate Price in California (Dollars per Thousand Cubic Feet)","California Price of ...

  3. Energy Upgrade California

    Office of Energy Efficiency and Renewable Energy (EERE)

    The Energy Upgrade California program serves as a one-stop shop for California homeowners who want to improve the energy efficiency of their homes. The program connects homeowners with qualified...

  4. Lithium-based Technologies | Y-12 National Security Complex

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Lithium-based Technologies Lithium-based Technologies Y-12's 60 years of rich lithium operational history and expertise make it the clear choice for deployment of new lithium-based ...

  5. Lithium ion conducting ionic electrolytes

    DOEpatents

    Angell, C. Austen; Xu, Kang; Liu, Changle

    1996-01-01

    A liquid, predominantly lithium-conducting, ionic electrolyte is described which has exceptionally high conductivity at temperatures of 100.degree. C. or lower, including room temperature. It comprises molten lithium salts or salt mixtures in which a small amount of an anionic polymer lithium salt is dissolved to stabilize the liquid against recrystallization. Further, a liquid ionic electrolyte which has been rubberized by addition of an extra proportion of anionic polymer, and which has good chemical and electrochemical stability, is described. This presents an attractive alternative to conventional salt-in-polymer electrolytes which are not cationic conductors.

  6. Lithium ion conducting ionic electrolytes

    DOEpatents

    Angell, C.A.; Xu, K.; Liu, C.

    1996-01-16

    A liquid, predominantly lithium-conducting, ionic electrolyte is described which has exceptionally high conductivity at temperatures of 100 C or lower, including room temperature. It comprises molten lithium salts or salt mixtures in which a small amount of an anionic polymer lithium salt is dissolved to stabilize the liquid against recrystallization. Further, a liquid ionic electrolyte which has been rubberized by addition of an extra proportion of anionic polymer, and which has good chemical and electrochemical stability, is described. This presents an attractive alternative to conventional salt-in-polymer electrolytes which are not cationic conductors. 4 figs.

  7. Anodes for rechargeable lithium batteries

    DOEpatents

    Thackeray, Michael M.; Kepler, Keith D.; Vaughey, John T.

    2003-01-01

    A negative electrode (12) for a non-aqueous electrochemical cell (10) with an intermetallic host structure containing two or more elements selected from the metal elements and silicon, capable of accommodating lithium within its crystallographic host structure such that when the host structure is lithiated it transforms to a lithiated zinc-blende-type structure. Both active elements (alloying with lithium) and inactive elements (non-alloying with lithium) are disclosed. Electrochemical cells and batteries as well as methods of making the negative electrode are disclosed.

  8. Cyanoethylated compounds as additives in lithium/lithium batteries

    DOEpatents

    Nagasubramanian, Ganesan

    1999-01-01

    The power loss of lithium/lithium ion battery cells is significantly reduced, especially at low temperatures, when about 1% by weight of an additive is incorporated in the electrolyte layer of the cells. The usable additives are organic solvent soluble cyanoethylated polysaccharides and poly(vinyl alcohol). The power loss decrease results primarily from the decrease in the charge transfer resistance at the interface between the electrolyte and the cathode.

  9. Modeling and Simulation of Lithium-Ion Batteries from a Systems Engineering Perspective

    SciTech Connect

    Ramadesigan, V.; Northrop, P. W. C.; De, S.; Santhanagopalan, S.; Braatz, R. D.; Subramanian, Venkat R.

    2012-01-01

    The lithium-ion battery is an ideal candidate for a wide variety of applications due to its high energy/power density and operating voltage. Some limitations of existing lithium-ion battery technology include underutilization, stress-induced material damage, capacity fade, and the potential for thermal runaway. This paper reviews efforts in the modeling and simulation of lithium-ion batteries and their use in the design of better batteries. Likely future directions in battery modeling and design including promising research opportunities are outlined.

  10. Silica Precipitation and Lithium Sorption

    SciTech Connect

    Jay Renew

    2015-09-20

    This file contains silica precipitation and lithium sorption data from the project. The silica removal data is corrected from the previous submission. The previous submission did not take into account the limit of detection of the ICP-MS procedure.

  11. Air breathing lithium power cells

    DOEpatents

    Farmer, Joseph C.

    2014-07-15

    A cell suitable for use in a battery according to one embodiment includes a catalytic oxygen cathode; a stabilized zirconia electrolyte for selective oxygen anion transport; a molten salt electrolyte; and a lithium-based anode. A cell suitable for use in a battery according to another embodiment includes a catalytic oxygen cathode; an electrolyte; a membrane selective to molecular oxygen; and a lithium-based anode.

  12. California Department of Transportation | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Transportation Jump to: navigation, search Name: California Department of Transportation Place: Sacramento, California References: California Department of Transportation1 This...

  13. Workplace Charging Challenge Partner: University of California...

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    California, Santa Barbara Workplace Charging Challenge Partner: University of California, Santa Barbara Workplace Charging Challenge Partner: University of California, Santa ...

  14. California State University, Chico | Department of Energy

    Energy.gov [DOE] (indexed site)

    Mechatronic Engineering; Yuanyuan Ju, Mechanical Engineering California State University, Chico California State University, Chico California State University, Chico Team ...

  15. CALIFORNIA VALLEY SOLAR RANCH | Department of Energy

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    CALIFORNIA VALLEY SOLAR RANCH CALIFORNIA VALLEY SOLAR RANCH CALIFORNIA VALLEY SOLAR RANCH CALIFORNIA VALLEY SOLAR RANCH CALIFORNIA VALLEY SOLAR RANCH CALIFORNIA VALLEY SOLAR RANCH CALIFORNIA VALLEY SOLAR RANCH CALIFORNIA VALLEY SOLAR RANCH CALIFORNIA VALLEY SOLAR RANCH CALIFORNIA VALLEY SOLAR RANCH CALIFORNIA VALLEY SOLAR RANCH PROJECT SUMMARY In September 2011, the Department of Energy issued a $1.2 billion loan guarantee to finance California Valley Solar Ranch, a 250-MW photovoltaic (PV)

  16. Go Solar California | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Solar California Jump to: navigation, search Logo: Go Solar California Name: Go Solar California Place: San Francisco, California Zip: 94120 Region: Bay Area Website:...

  17. Lithium-Ion Battery with Higher Charge Capacity - Energy Innovation Portal

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Energy Storage Energy Storage Find More Like This Return to Search Lithium-Ion Battery with Higher Charge Capacity University of Minnesota DOE Grant Recipients Contact GRANT About This Technology Technology Marketing Summary Zirconate Based Cathode Material Lithium-ion batteries (LIBs) typically use a cobalt compound as the cathode material. Cobalt oxides are relatively expensive and scarce. An innovative zirconate-based cathode material developed at the University of Minnesota has the potential

  18. Ceramic-Metal Composites for Electrodes of Lithium Ion Batteries - Energy

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Innovation Portal Energy Storage Energy Storage Advanced Materials Advanced Materials Find More Like This Return to Search Ceramic-Metal Composites for Electrodes of Lithium Ion Batteries Lawrence Berkeley National Laboratory Contact LBL About This Technology Technology Marketing SummaryLithium's high energy density makes it desirable for use in rechargeable batteries, but its tendency to form dendrites has limited its use to primary batteries. This limitation can be addressed by using

  19. Where do California's greenhouse gases come from?

    ScienceCinema

    Fischer, Marc

    2013-05-29

    Last March, more than two years after California passed legislation to slash greenhouse gas emissions 25 percent by 2020, Lawrence Berkeley National Laboratory scientist Marc Fischer boarded a Cessna loaded with air monitoring equipment and crisscrossed the skies above Sacramento and the Bay Area. Instruments aboard the aircraft measured a cocktail of greenhouse gases: carbon dioxide from fossil fuel use, methane from livestock and landfills, CO2 from refineries and power plants, traces of nitrous oxide from agriculture and fuel use, and industrially produced other gases like refrigerants. The flight was part of the Airborne Greenhouse Gas Emissions Survey, a collaboration between Berkeley Lab, the National Oceanic and Atmospheric Administration, and the University of California, and UC Davis to pinpoint the sources of greenhouse gases in central California. The survey is intended to improve inventories of the states greenhouse gas emissions, which in turn will help scientists verify the emission reductions mandated by AB-32, the legislation enacted by California in 2006.

  20. Where do California's greenhouse gases come from?

    SciTech Connect

    Fischer, Marc

    2009-01-01

    Last March, more than two years after California passed legislation to slash greenhouse gas emissions 25 percent by 2020, Lawrence Berkeley National Laboratory scientist Marc Fischer boarded a Cessna loaded with air monitoring equipment and crisscrossed the skies above Sacramento and the Bay Area. Instruments aboard the aircraft measured a cocktail of greenhouse gases: carbon dioxide from fossil fuel use, methane from livestock and landfills, CO2 from refineries and power plants, traces of nitrous oxide from agriculture and fuel use, and industrially produced other gases like refrigerants. The flight was part of the Airborne Greenhouse Gas Emissions Survey, a collaboration between Berkeley Lab, the National Oceanic and Atmospheric Administration, and the University of California, and UC Davis to pinpoint the sources of greenhouse gases in central California. The survey is intended to improve inventories of the states greenhouse gas emissions, which in turn will help scientists verify the emission reductions mandated by AB-32, the legislation enacted by California in 2006.

  1. Amador County, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Facility Places in Amador County, California Amador City, California Ione, California Jackson, California Plymouth, California Sutter Creek, California Retrieved from "http:...

  2. Tehama County, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    California Manton, California Mineral, California Rancho Tehama Reserve, California Red Bluff, California Tehama, California Retrieved from "http:en.openei.orgw...

  3. High performance discharges in the Lithium Tokamak eXperiment with liquid lithium walls

    SciTech Connect

    Schmitt, J. C.; Bell, R. E.; Boyle, D. P.; Esposti, B.; Kaita, R.; Kozub, T.; LeBlanc, B. P.; Lucia, M.; Maingi, R.; Majeski, R.; Merino, E.; Punjabi-Vinoth, S.; Tchilingurian, G.; Capece, A.; Koel, B.; Roszell, J.; Biewer, T. M.; Gray, T. K.; Kubota, S.; Beiersdorfer, P.; and others

    2015-05-15

    The first-ever successful operation of a tokamak with a large area (40% of the total plasma surface area) liquid lithium wall has been achieved in the Lithium Tokamak eXperiment (LTX). These results were obtained with a new, electron beam-based lithium evaporation system, which can deposit a lithium coating on the limiting wall of LTX in a five-minute period. Preliminary analyses of diamagnetic and other data for discharges operated with a liquid lithium wall indicate that confinement times increased by 10× compared to discharges with helium-dispersed solid lithium coatings. Ohmic energy confinement times with fresh lithium walls, solid and liquid, exceed several relevant empirical scaling expressions. Spectroscopic analysis of the discharges indicates that oxygen levels in the discharges limited on liquid lithium walls were significantly reduced compared to discharges limited on solid lithium walls. Tokamak operations with a full liquid lithium wall (85% of the total plasma surface area) have recently started.

  4. Protective lithium ion conducting ceramic coating for lithium metal anodes and associate method

    DOEpatents

    Bates, John B.

    1994-01-01

    A battery structure including a cathode, a lithium metal anode and an electrolyte disposed between the lithium anode and the cathode utilizes a thin-film layer of lithium phosphorus oxynitride overlying so as to coat the lithium anode and thereby separate the lithium anode from the electrolyte. If desired, a preliminary layer of lithium nitride may be coated upon the lithium anode before the lithium phosphorous oxynitride is, in turn, coated upon the lithium anode so that the separation of the anode and the electrolyte is further enhanced. By coating the lithium anode with this material lay-up, the life of the battery is lengthened and the performance of the battery is enhanced.

  5. Quantification of Electrochemical Nanoscale Processes in Lithium...

    Office of Scientific and Technical Information (OSTI)

    In addition, extensive worldwide research efforts are now being devoted to more advanced "beyond Li-ion" battery chemistries - such as lithium-sulfur (Li-S) and lithium-air (Li-O2) ...

  6. Michael Thackeray on Lithium-air Batteries

    ScienceCinema

    Thackeray, Michael

    2016-07-12

    Michael Thackeray, Distinguished Fellow at Argonne National Laboratory, speaks on the new technology Lithium-air batteries, which could potentially increase energy density by 5-10 times over lithium-ion batteries.

  7. Active Radiatiive Liquid Lithium (metal) Divertor | Princeton...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Active Radiatiive Liquid Lithium (metal) Divertor Developing a reactor-compatible divertor ... Application of Lithium (Li) in NSTX resulted in improved H-mode confinement, H-mode power ...

  8. Michael Thackery on Lithium-air Batteries

    ScienceCinema

    Michael Thackery

    2010-01-08

    Michael Thackery, Distinguished Fellow at Argonne National Laboratory, speaks on the new technology Lithium-air batteries, which could potentially increase energy density by 5-10 times over lithium-ion batteries.

  9. Khalil Amine on Lithium-air Batteries

    ScienceCinema

    Khalil Amine

    2016-07-12

    Khalil Amine, materials scientist at Argonne National Laboratory, speaks on the new technology Lithium-air batteries, which could potentially increase energy density by 5-10 times over lithium-ion batteries.

  10. Khalil Amine on Lithium-air Batteries

    SciTech Connect

    Khalil Amine

    2009-09-14

    Khalil Amine, materials scientist at Argonne National Laboratory, speaks on the new technology Lithium-air batteries, which could potentially increase energy density by 5-10 times over lithium-ion batteries.

  11. Recent advances in lithium ion technology

    SciTech Connect

    Levy, S.C.

    1995-01-01

    Lithium ion technology is based on the use of lithium intercalating electrodes. Carbon is the most commonly used anode material, while the cathode materials of choice have been layered lithium metal chalcogenides (LiMX{sub 2}) and lithium spinel-type compounds. Electrolytes may be either organic liquids or polymers. Although the first practical use of graphite intercalation compounds as battery anodes was reported in 1981 for molten salt cells (1) and in 1983 for ambient temperature systems (2) it was not until Sony Energytech announced a new lithium ion rechargeable cell containing a lithium ion intercalating carbon anode in 1990, that interest peaked. The reason for this heightened interest is that these cells have the high energy density, high voltage and fight weight of metallic lithium systems plus a very long cycle life, but without the disadvantages of dendrite formation on charge and the safety considerations associated with metallic lithium.

  12. Multi-layered, chemically bonded lithium-ion and lithium/air batteries

    DOEpatents

    Narula, Chaitanya Kumar; Nanda, Jagjit; Bischoff, Brian L; Bhave, Ramesh R

    2014-05-13

    Disclosed are multilayer, porous, thin-layered lithium-ion batteries that include an inorganic separator as a thin layer that is chemically bonded to surfaces of positive and negative electrode layers. Thus, in such disclosed lithium-ion batteries, the electrodes and separator are made to form non-discrete (i.e., integral) thin layers. Also disclosed are methods of fabricating integrally connected, thin, multilayer lithium batteries including lithium-ion and lithium/air batteries.

  13. Electronic structural and electrochemical properties of lithium...

    Office of Scientific and Technical Information (OSTI)

    Journal Article: Electronic structural and electrochemical properties of lithium zirconates and ... Resource Relation: Journal Name: Journal of the Electrochemical Society; ...

  14. Lithium Technology Corporation | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Technology Corporation Jump to: navigation, search Name: Lithium Technology Corporation Place: Plymouth Meeting, Pennsylvania Zip: PA 19462 Sector: Vehicles Product:...

  15. Nanocomposite Materials for Lithium Ion Batteries

    SciTech Connect

    2011-05-31

    Fact sheet describing development and application of processing and process control for nanocomposite materials for lithium ion batteries

  16. Ultrathin Li3VO4 Nanoribbon/Graphene Sandwich-Like Nanostructures...

    Office of Scientific and Technical Information (OSTI)

    Title: Ultrathin Li3VO4 NanoribbonGraphene Sandwich-Like Nanostructures with Ultrahigh Lithium ion Storage Properties Two-dimensional (2D) "graphene-like" inorganic materials, ...

  17. Magnetism in LithiumOxygen Discharge Product

    SciTech Connect

    Lu, Jun; Jung, Hun-Ji; Lau, Kah Chun; Zhang, Zhengcheng; Schlueter, John A.; Du, Peng; Assary, Rajeev S.; Greeley, Jeffrey P.; Ferguson, Glen A.; Wang, Hsien-Hau; Hassoun, Jusef; Iddir, Hakim; Zhou, Jigang; Zuin, Lucia; Hu, Yongfeng; Sun, Yang-Kook; Scrosati, Bruno; Curtiss, Larry A.; Amine, Khalil

    2013-05-13

    Nonaqueous lithiumoxygen batteries have a much superior theoretical gravimetric energy density compared to conventional lithium-ion batteries, and thus could render long-range electric vehicles a reality. A molecular-level understanding of the reversible formation of lithium peroxide in these batteries, the properties of major/minor discharge products, and the stability of the nonaqueous electrolytes is required to achieve successful lithiumoxygen batteries. We demonstrate that the major discharge product formed in the lithiumoxygen cell, lithium peroxide, exhibits a magnetic moment. These results are based on dc-magnetization measurements and a lithium oxygen cell containing an ether-based electrolyte. The results are unexpected because bulk lithium peroxide has a significant band gap. Density functional calculations predict that superoxide- type surface oxygen groups with unpaired electrons exist on stoichiometric lithium peroxide crystalline surfaces and on nanoparticle surfaces; these computational results are consistent with the magnetic measurement of the discharged lithium peroxide product as well as EPR measurements on commercial lithium peroxide. The presence of superoxide-type surface oxygen groups with spin can play a role in the reversible formation and decomposition of lithium peroxide as well as the reversible formation and decomposition of electrolyte molecules.

  18. Anode materials for lithium-ion batteries

    DOEpatents

    Sunkara, Mahendra Kumar; Meduri, Praveen; Sumanasekera, Gamini

    2014-12-30

    An anode material for lithium-ion batteries is provided that comprises an elongated core structure capable of forming an alloy with lithium; and a plurality of nanostructures placed on a surface of the core structure, with each nanostructure being capable of forming an alloy with lithium and spaced at a predetermined distance from adjacent nanostructures.

  19. Solid composite electrolytes for lithium batteries

    DOEpatents

    Kumar, Binod; Scanlon, Jr., Lawrence G.

    2000-01-01

    Solid composite electrolytes are provided for use in lithium batteries which exhibit moderate to high ionic conductivity at ambient temperatures and low activation energies. In one embodiment, a ceramic-ceramic composite electrolyte is provided containing lithium nitride and lithium phosphate. The ceramic-ceramic composite is also preferably annealed and exhibits an activation energy of about 0.1 eV.

  20. Conductive lithium storage electrode

    DOEpatents

    Chiang, Yet-Ming; Chung, Sung-Yoon; Bloking, Jason T.; Andersson, Anna M.

    2012-04-03

    A compound comprising a composition A.sub.x(M'.sub.1-aM''.sub.a).sub.y(XD.sub.4).sub.z, A.sub.x(M'.sub.1-aM''.sub.a).sub.y(DXD.sub.4).sub.z, or A.sub.x(M'.sub.1-aM''.sub.a).sub.y(X.sub.2D.sub.7).sub.z, and have values such that x, plus y(1-a) times a formal valence or valences of M', plus ya times a formal valence or valence of M'', is equal to z times a formal valence of the XD.sub.4, X.sub.2D.sub.7, or DXD.sub.4 group; or a compound comprising a composition (A.sub.1-aM''.sub.a).sub.xM'.sub.y(XD.sub.4).sub.z, (A.sub.1-aM''.sub.a).sub.xM'.sub.y(DXD.sub.4).sub.z (A.sub.1-aM''.sub.a).sub.xM'.sub.y(X.sub.2D.sub.7).sub.z and have values such that (1-a).sub.x plus the quantity ax times the formal valence or valences of M'' plus y times the formal valence or valences of M' is equal to z times the formal valence of the XD.sub.4, X.sub.2D.sub.7 or DXD.sub.4 group. In the compound, A is at least one of an alkali metal and hydrogen, M' is a first-row transition metal, X is at least one of phosphorus, sulfur, arsenic, molybdenum, and tungsten, M'' any of a Group IIA, IIIA, IVA, VA, VIA, VIIA, VIIIA, IB, IIB, IIIB, IVB, VB, and VIB metal, D is at least one of oxygen, nitrogen, carbon, or a halogen, 0.0001lithium phosphate that can intercalate lithium or hydrogen. The compound can be used in an electrochemical device including electrodes and storage batteries and can have a gravimetric capacity of at least about 80 mAh/g while being charged/discharged at greater than about C rate of the compound.

  1. Conductive lithium storage electrode

    DOEpatents

    Chiang, Yet-Ming; Chung, Sung-Yoon; Bloking, Jason T.; Andersson, Anna M.

    2008-03-18

    A compound comprising a composition A.sub.x(M'.sub.1-aM''.sub.a).sub.y(XD.sub.4).sub.z, A.sub.x(M'.sub.1-aM''.sub.a).sub.y(DXD.sub.4).sub.z, or A.sub.x(M'.sub.1-aM''.sub.a).sub.y(X.sub.2D.sub.7).sub.z, and have values such that x, plus y(1-a) times a formal valence or valences of M', plus ya times a formal valence or valence of M'', is equal to z times a formal valence of the XD.sub.4, X.sub.2D.sub.7, or DXD.sub.4 group; or a compound comprising a composition (A.sub.1-aM''.sub.a).sub.xM'.sub.y(XD.sub.4).sub.z, (A.sub.1-aM''.sub.a).sub.xM'.sub.y(DXD.sub.4).sub.z(A.sub.1-aM''.sub.a).s- ub.xM'.sub.y(X.sub.2D.sub.7).sub.z and have values such that (1-a).sub.x plus the quantity ax times the formal valence or valences of M'' plus y times the formal valence or valences of M' is equal to z times the formal valence of the XD.sub.4, X.sub.2D.sub.7 or DXD.sub.4 group. In the compound, A is at least one of an alkali metal and hydrogen, M' is a first-row transition metal, X is at least one of phosphorus, sulfur, arsenic, molybdenum, and tungsten, M'' any of a Group IIA, IIIA, IVA, VA, VIA, VIIA, VIIIA, IB, IIB, IIIB, IVB, VB, and VIB metal, D is at least one of oxygen, nitrogen, carbon, or a halogen, 0.0001lithium phosphate that can intercalate lithium or hydrogen. The compound can be used in an electrochemical device including electrodes and storage batteries and can have a gravimetric capacity of at least about 80 mAh/g while being charged/discharged at greater than about C rate of the compound.

  2. California Energy Incentive Programs

    Energy.gov [DOE]

    Report from the Federal Energy Management Program (FEMP) discusses annual update on key energy issues and financial opportunities for federal sites in California.

  3. California Energy Commission

    Energy.gov [DOE] (indexed site)

    California Energy Commission Quadrennial Water Review Comments - June 19, 2014 Water-Energy Nexus Water and energy systems are inextricably linked -- producing energy uses large ...

  4. CaliforniaFIRST

    Office of Energy Efficiency and Renewable Energy (EERE)

    Eligibility is generally determined by the property records and value, and the property must meet general underwriting criteria established by the California Statewide Communities Development Aut...

  5. university of california

    National Nuclear Security Administration (NNSA)

    Led by University of California, Berkeley Awarded 25M NNSA Grant for Nuclear Science and Security Research http:nnsa.energy.govmediaroompressreleases...

  6. California Maritime Academy 2014

    Office of Energy Efficiency and Renewable Energy (EERE)

    The California Maritime Collegiate Wind Competition team, CMAWind, developed a small wind turbine to provide power for cell phones and LED light bulbs in rural areas of Africa.

  7. Lithium metal oxide electrodes for lithium cells and batteries

    DOEpatents

    Thackeray, Michael M.; Johnson, Christopher S.; Amine, Khalil; Kim, Jaekook

    2006-11-14

    A lithium metal oxide positive electrode for a non-aqueous lithium cell is disclosed. The cell is prepared in its initial discharged state and has a general formula xLiMO.sub.2.(1-x)Li.sub.2M'O.sub.3 in which 0

  8. Lithium metal oxide electrodes for lithium cells and batteries

    DOEpatents

    Thackeray, Michael M.; Johnson, Christopher S.; Amine, Khalil; Kim, Jaekook

    2004-01-13

    A lithium metal oxide positive electrode for a non-aqueous lithium cell is disclosed. The cell is prepared in its initial discharged state and has a general formula xLiMO.sub.2.(1-x)Li.sub.2 M'O.sub.3 in which 0

  9. Facile hydrothermal method synthesis of coralline-like Li{sub 1.2}Mn{sub 0.54}Ni{sub 0.13}Co{sub 0.13}O{sub 2} hierarchical architectures as superior cathode materials for lithium-ion batteries

    SciTech Connect

    Hou, Xianhua; Huang, Yanling; Ma, Shaomeng; Zou, Xiaoli; Hu, Shejun; Wu, Yuping

    2015-03-15

    Highlights: • A coralline-like Li{sub 1.20}Mn{sub 0.54}Ni{sub 0.13}Co{sub 0.13}O{sub 2} cathode was synthesized by hydrothermal method. • Initial discharge capacity of 250.2 mAh g{sup −1} for the cathode was obtained at 0.1 C. • A high reversible specific capacity of 210.2 mAh g{sup −1} after 100 cycles was acquired. • The high capacity retention of 84.5% was obtained even after 200 cycles at 10 C. - Abstract: A coralline-like lithium-rich layered cathode material with homogeneous composition of Li{sub 1.20}Mn{sub 0.54}Ni{sub 0.13}Co{sub 0.13}O{sub 2} has been successfully synthesized via a facile ethanolamine (EA)-mediated hydrothermal method route, with subsequent calcination at 850 °C. An initial specific discharge capacity of 250.2 mAh g{sup −1} and a reversible specific capacity of 210.2 mAh g{sup −1} after 100 cycles at a constant density of 25 mA g{sup −1} (1 C = 250 mA g{sup −1}) are acquired. Even at 10 C, it still delivers a discharge capacity of approximately 100 mA h g{sup −1}, thereby indicating its excellent high power performance. The sample also shows enhanced cycling performance with 88.5%, 79.9% and 90.5% of capacity retention after 100 cycles at 0.5, 5 and 10 C rates, respectively. Besides, 84.5% of initial capacity is retained even after 200 cycles at 10 C. Consequently, the fascinating electrochemical performance may facilitate the coralline-like LMNCO composite to be a promising alternative cathode for LIBs with a high application potential.

  10. Electrochromic Nickel Oxide Simultaneously Doped with Lithium and a Metal

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Dopant - Energy Innovation Portal Advanced Materials Advanced Materials Find More Like This Return to Search Electrochromic Nickel Oxide Simultaneously Doped with Lithium and a Metal Dopant National Renewable Energy Laboratory Contact NREL About This Technology Technology Marketing Summary Certain materials, referred to as electrochromic materials, are known to change their optical properties in response to the application of an electrical potential. This property has been taken advantage of

  11. High Power Performance Lithium Ion Battery - Energy Innovation Portal

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Energy Storage Energy Storage Advanced Materials Advanced Materials Find More Like This Return to Search High Power Performance Lithium Ion Battery Lawrence Berkeley National Laboratory Contact LBL About This Technology Hybrid Pulse Power Characterization Test (HPPC) results for 3 coin cells of various AB:PVDF ratios. Hybrid Pulse Power Characterization Test (HPPC) results for 3 coin cells of various AB:PVDF ratios. Technology Marketing SummaryGao Liu and colleagues at Berkeley Lab have

  12. Thin-film Rechargeable Lithium Batteries

    DOE R&D Accomplishments

    Dudney, N. J.; Bates, J. B.; Lubben, D.

    1995-06-01

    Thin film rechargeable lithium batteries using ceramic electrolyte and cathode materials have been fabricated by physical deposition techniques. The lithium phosphorous oxynitride electrolyte has exceptional electrochemical stability and a good lithium conductivity. The lithium insertion reaction of several different intercalation materials, amorphous V{sub 2}O{sub 5}, amorphous LiMn{sub 2}O{sub 4}, and crystalline LiMn{sub 2}O{sub 4} films, have been investigated using the completed cathode/electrolyte/lithium thin film battery.

  13. Itron (California) | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Itron (California) Jump to: navigation, search Name: Itron Address: 11236 El Camino Real Place: San Diego, California Zip: 92130 Region: Southern CA Area Sector: Efficiency...

  14. California Register | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    search OpenEI Reference LibraryAdd to library Legal Document- OtherOther: California RegisterLegal Abstract California Register, current through August 7, 2014....

  15. Surface protected lithium-metal-oxide electrodes

    DOEpatents

    Thackeray, Michael M.; Kang, Sun-Ho

    2016-04-05

    A lithium-metal-oxide positive electrode having a layered or spinel structure for a non-aqueous lithium electrochemical cell and battery is disclosed comprising electrode particles that are protected at the surface from undesirable effects, such as electrolyte oxidation, oxygen loss or dissolution by one or more lithium-metal-polyanionic compounds, such as a lithium-metal-phosphate or a lithium-metal-silicate material that can act as a solid electrolyte at or above the operating potential of the lithium-metal-oxide electrode. The surface protection significantly enhances the surface stability, rate capability and cycling stability of the lithium-metal-oxide electrodes, particularly when charged to high potentials.

  16. Solid solution lithium alloy cermet anodes

    DOEpatents

    Richardson, Thomas J.

    2013-07-09

    A metal-ceramic composite ("cermet") has been produced by a chemical reaction between a lithium compound and another metal. The cermet has advantageous physical properties, high surface area relative to lithium metal or its alloys, and is easily formed into a desired shape. An example is the formation of a lithium-magnesium nitride cermet by reaction of lithium nitride with magnesium. The reaction results in magnesium nitride grains coated with a layer of lithium. The nitride is inert when used in a battery. It supports the metal in a high surface area form, while stabilizing the electrode with respect to dendrite formation. By using an excess of magnesium metal in the reaction process, a cermet of magnesium nitride is produced, coated with a lithium-magnesium alloy of any desired composition. This alloy inhibits dendrite formation by causing lithium deposited on its surface to diffuse under a chemical potential into the bulk of the alloy.

  17. Lithium-loaded liquid scintillators

    DOEpatents

    Dai, Sheng; Kesanli, Banu; Neal, John S.

    2012-05-15

    The invention is directed to a liquid scintillating composition containing (i) one or more non-polar organic solvents; (ii) (lithium-6)-containing nanoparticles having a size of up to 10 nm and surface-capped by hydrophobic molecules; and (iii) one or more fluorophores. The invention is also directed to a liquid scintillator containing the above composition.

  18. Anode material for lithium batteries

    DOEpatents

    Belharouak, Ilias; Amine, Khalil

    2008-06-24

    Primary and secondary Li-ion and lithium-metal based electrochemical cell system. The suppression of gas generation is achieved through the addition of an additive or additives to the electrolyte system of respective cell, or to the cell itself whether it be a liquid, a solid- or plastized polymer electrolyte system. The gas suppression additives are primarily based on unsaturated hydrocarbons.

  19. Anode material for lithium batteries

    DOEpatents

    Belharouak, Ilias; Amine, Khalil

    2011-04-05

    Primary and secondary Li-ion and lithium-metal based electrochemical cell systems. The suppression of gas generation is achieved through the addition of an additive or additives to the electrolyte system of respective cell, or to the cell itself whether it be a liquid, a solid- or plasticized polymer electrolyte system. The gas suppression additives are primarily based on unsaturated hydrocarbons.

  20. Anode material for lithium batteries

    DOEpatents

    Belharouak, Ilias; Amine, Khalil

    2012-01-31

    Primary and secondary Li-ion and lithium-metal based electrochemical cell systems. The suppression of gas generation is achieved through the addition of an additive or additives to the electrolyte system of respective cell, or to the cell itself whether it be a liquid, a solid- or plasticized polymer electrolyte system. The gas suppression additives are primarily based on unsaturated hydrocarbons.

  1. Field desorption of lithium fluoride

    SciTech Connect

    Stintz, A.; Panitz, J.A. )

    1995-03-01

    Layers of lithium fluoride (LiF), [similar to]10 nm thick, were field desorbed from iridium substrates at temperatures between 25 and 600 [degree]C. The electric field was increased until desorption of the salt layer occurred. Combined mass spectroscopy and field desorption microscopy characterized the desorption process. During desorption, ions of the form (LiF)[sub [ital n

  2. Chemical Shuttle Additives in Lithium Ion Batteries

    SciTech Connect

    Patterson, Mary

    2013-03-31

    than NMC) and the DDB is useful for lithium ion cells with LFP cathodes (potential that is lower than NMC). A 4.5 V class redox shuttle provided by Argonne National Laboratory was evaluated which provides a few cycles of overcharge protection for lithium ion cells containing NMC cathodes but it is not stable enough for consideration. Thus, a redox shuttle with an appropriate redox potential and sufficient chemical and electrochemical stability for commercial use in larger format lithium ion cells with NMC cathodes was not found. Molecular imprinting of the redox shuttle molecule during solid electrolyte interphase (SEI) layer formation likely contributes to the successful reduction of oxidized redox shuttle species at carbon anodes. This helps to understand how a carbon anode covered with an SEI layer, that is supposed to be electrically insulating, can reduce the oxidized form of a redox shuttle.

  3. ALS Technique Gives Novel View of Lithium Battery Dendrite Growth

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    ALS Technique Gives Novel View of Lithium Battery Dendrite Growth ALS Technique Gives Novel View of Lithium Battery Dendrite Growth Print Thursday, 24 April 2014 09:46 Lithium-ion ...

  4. Effect of Lithium PFC Coatings on NSTX Density Control (Journal...

    Office of Scientific and Technical Information (OSTI)

    Effect of Lithium PFC Coatings on NSTX Density Control Citation Details In-Document Search Title: Effect of Lithium PFC Coatings on NSTX Density Control Lithium coatings on the ...

  5. Alpine County, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    California Bear Valley, California Kirkwood, California Markleeville, California Mesa Vista, California Retrieved from "http:en.openei.orgwindex.php?titleAlpineCounty,Cali...

  6. San Bernardino County, California: Energy Resources | Open Energy...

    OpenEI (Open Energy Information) [EERE & EIA]

    2 Solar Power Plant Places in San Bernardino County, California Adelanto, California Apple Valley, California Barstow, California Big Bear City, California Big Bear Lake,...

  7. Sutter County, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Subtype B. Places in Sutter County, California Live Oak, California Sutter, California Tierra Buena, California Yuba City, California Retrieved from "http:en.openei.orgw...

  8. A Material Change: Bringing Lithium Production Back to America | Department

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    of Energy A Material Change: Bringing Lithium Production Back to America A Material Change: Bringing Lithium Production Back to America June 29, 2012 - 5:34pm Addthis The Rockwood Lithium manufacturing facility in Kings Mountain, North Carolina. | Photo courtesy of Rockwood Lithium. The Rockwood Lithium manufacturing facility in Kings Mountain, North Carolina. | Photo courtesy of Rockwood Lithium. Niketa Kumar Niketa Kumar Public Affairs Specialist, Office of Public Affairs Between 1980 and

  9. Lithium-aluminum-iron electrode composition

    DOEpatents

    Kaun, Thomas D.

    1979-01-01

    A negative electrode composition is presented for use in a secondary electrochemical cell. The cell also includes an electrolyte with lithium ions such as a molten salt of alkali metal halides or alkaline earth metal halides that can be used in high-temperature cells. The cell's positive electrode contains a a chalcogen or a metal chalcogenide as the active electrode material. The negative electrode composition includes up to 50 atom percent lithium as the active electrode constituent in an alloy of aluminum-iron. Various binary and ternary intermetallic phases of lithium, aluminum and iron are formed. The lithium within the intermetallic phase of Al.sub.5 Fe.sub.2 exhibits increased activity over that of lithium within a lithium-aluminum alloy to provide an increased cell potential of up to about 0.25 volt.

  10. Preparation of lithium-ion battery anodes using lignin (Journal...

    Office of Scientific and Technical Information (OSTI)

    Journal Article: Preparation of lithium-ion battery anodes using lignin Citation Details In-Document Search Title: Preparation of lithium-ion battery anodes using lignin Authors:...

  11. Novel Electrolytes for Lithium Ion Batteries Lucht, Brett L 25...

    Office of Scientific and Technical Information (OSTI)

    Electrolytes for Lithium Ion Batteries Lucht, Brett L 25 ENERGY STORAGE We have been investigating three primary areas related to lithium ion battery electrolytes. First, we have...

  12. Lithium Tokamak Experiment (LTX) | Princeton Plasma Physics Lab

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Lithium Tokamak Experiment (LTX) The Lithium Tokamak Experiment (LTX) produced its first plasma in September, 2008. The new device will continue the promising, innovative work...

  13. Addressing the Voltage Fade Issue with Lithium-Manganese-Rich...

    Energy.gov [DOE] (indexed site)

    More Documents & Publications Studies on Lithium Manganese Rich MNC Composite Cathodes ... Addressing the Voltage Fade Issue with Lithium-Manganese-Rich Oxide Cathode Materials

  14. Expansion of Novolyte Capacity for Lithium Ion Electrolyte Production...

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    More Documents & Publications Expansion of Novolyte Capacity for Lithium Ion Electrolyte Production Expansion of Novolyte Capacity for Lithium Ion Electrolyte Production FY 2011

  15. Deuterium Uptake in Magnetic Fusion Devices with Lithium Conditioned...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Fusion Devices with Lithium Conditioned Carbon Walls American Fusion News Category: U.S. Universities Link: Deuterium Uptake in Magnetic Fusion Devices with Lithium ...

  16. Expansion of Novolyte Capacity for Lithium Ion Electrolyte Production...

    Energy.gov [DOE] (indexed site)

    More Documents & Publications Expansion of Novolyte Capacity for Lithium Ion Electrolyte Production Expansion of Novolyte Capacity for Lithium Ion Electrolyte Production FY 2012

  17. Lithium Ion Electrode Production NDE and QC Considerations |...

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    Lithium Ion Electrode Production NDE and QC Considerations Lithium Ion Electrode Production NDE and QC Considerations Review of Oak Ridge process and QC activities by David Wood, ...

  18. Vacuum Attachment for Collection of Lithium Powder ---- Inventor...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    of Lithium Powder ---- Inventor(s) Hans Schneider and Stephan Jurczynski The Vacuum Attachment is part of an integrated system designed to collect Lithium (Li) Power for ...

  19. Lithium Tokamak Experiment (LTX) | Princeton Plasma Physics Lab

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Lithium Tokamak Experiment (LTX) The Lithium Tokamak Experiment (LTX) produced its first plasma in September, 2008. The new device will continue the promising, innovative work ...

  20. Layered Electrodes for Lithium Cells and Batteries | Argonne...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Electrodes for Lithium Cells and Batteries Technology available for licensing: Layered lithium metal oxide compounds for ultra-high-capacity, rechargeable cathodes Lowers cost to ...

  1. Novel Redox Shuttles for Overcharge Protection of Lithium-Ion...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Protection of Lithium-Ion Batteries Technology available for licensing: Electrolytes containing novel redox shuttles (electron transporters) for lithium-ion batteries ...

  2. simulate the dynamic distribution of lithium in the electrode

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    simulate the dynamic distribution of lithium in the electrode - Sandia Energy Energy ... simulate the dynamic distribution of lithium in the electrode HomeTag:simulate the ...

  3. Closing the Lithium-ion Battery Life Cycle: Poster handout |...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Closing the Lithium-ion Battery Life Cycle: Poster handout Title Closing the Lithium-ion Battery Life Cycle: Poster handout Publication Type Miscellaneous Year of Publication 2014...

  4. Additives and Cathode Materials for High-Energy Lithium Sulfur...

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    Additives and Cathode Materials for High-Energy Lithium Sulfur Batteries Additives and Cathode Materials for High-Energy Lithium Sulfur Batteries 2013 DOE Hydrogen and Fuel Cells...

  5. Development of Polymer Electrolytes for Advanced Lithium Batteries...

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    Polymer Electrolytes for Advanced Lithium Batteries Development of Polymer Electrolytes for Advanced Lithium Batteries 2013 DOE Hydrogen and Fuel Cells Program and Vehicle...

  6. Fact Sheet: Lithium-Ion Batteries for Stationary Energy Storage...

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    Fact Sheet: Lithium-Ion Batteries for Stationary Energy Storage (October 2012) Fact Sheet: Lithium-Ion Batteries for Stationary Energy Storage (October 2012) DOE's Energy Storage...

  7. Etna Resources soon to be Pan American Lithium | Open Energy...

    OpenEI (Open Energy Information) [EERE & EIA]

    Etna Resources soon to be Pan American Lithium Jump to: navigation, search Name: Etna Resources (soon to be Pan American Lithium) Place: Vancouver, British Columbia, Canada Zip:...

  8. Functional electrolyte for lithium-ion batteries (Patent) | DOEPatents

    Office of Scientific and Technical Information (OSTI)

    Data Explorer Search Results Functional electrolyte for lithium-ion batteries Title: Functional electrolyte for lithium-ion batteries Functional electrolyte solvents include ...

  9. Methods for making anodes for lithium ion batteries (Patent)...

    Office of Scientific and Technical Information (OSTI)

    Data Explorer Search Results Methods for making anodes for lithium ion batteries Title: Methods for making anodes for lithium ion batteries Methods for making composite anodes, ...

  10. Graphene-sulfur nanocomposites for rechargeable lithium-sulfur...

    Office of Scientific and Technical Information (OSTI)

    Title: Graphene-sulfur nanocomposites for rechargeable lithium-sulfur battery electrodes Rechargeable lithium-sulfur batteries having a cathode that includes a graphene-sulfur ...

  11. Solid-state lithium battery (Patent) | SciTech Connect

    Office of Scientific and Technical Information (OSTI)

    The present invention is directed to a higher power, thin film lithium-ion electrolyte on a metallic substrate, enabling mass-produced solid-state lithium batteries. ...

  12. High Rate and Stable Cycling of Lithium Metal Anode (Journal...

    Office of Scientific and Technical Information (OSTI)

    Title: High Rate and Stable Cycling of Lithium Metal Anode Lithium (Li) metal is an ideal anode material for rechargeable batteries. However, dendritic Li growth and limited ...

  13. Novel Electrolytes for Lithium Ion Batteries (Technical Report...

    Office of Scientific and Technical Information (OSTI)

    SciTech Connect Search Results Technical Report: Novel Electrolytes for Lithium Ion Batteries Citation Details In-Document Search Title: Novel Electrolytes for Lithium Ion ...

  14. Organosilicon-Based Electrolytes for Long-Life Lithium Primary...

    Office of Scientific and Technical Information (OSTI)

    Organosilicon-Based Electrolytes for Long-Life Lithium Primary Batteries Citation Details In-Document Search Title: Organosilicon-Based Electrolytes for Long-Life Lithium Primary ...

  15. Long life lithium batteries with stabilized electrodes (Patent...

    Office of Scientific and Technical Information (OSTI)

    Data Explorer Search Results Long life lithium batteries with stabilized electrodes Title: Long life lithium batteries with stabilized electrodes The present invention relates to ...

  16. Review of Reactivity Experiments for Lithium Ternary Alloys ...

    Office of Scientific and Technical Information (OSTI)

    The plant uses lithium in both the primary coolant and blanket; therefore, lithium related hazards are of primary concern. Reducing chemical reactivity is the primary motivation ...

  17. Can Automotive Battery Recycling Help Meet Lithium Demand? |...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Can Automotive Battery Recycling Help Meet Lithium Demand? Title Can Automotive Battery Recycling Help Meet Lithium Demand? Publication Type Presentation Year of Publication 2013...

  18. Neutronics Evaluation of Lithium-Based Ternary Alloys in IFE...

    Office of Scientific and Technical Information (OSTI)

    If the chemical reactivity of lithium could be overcome, the result would have a profound ... whilemore mitigating the chemical reactivity issues of pure lithium. less Authors: ...

  19. Lithium ion batteries with titania/graphene anodes (Patent) ...

    Office of Scientific and Technical Information (OSTI)

    Title: Lithium ion batteries with titaniagraphene anodes Lithium ion batteries having an anode comprising at least one graphene layer in electrical communication with titania to ...

  20. Lithium based electrochemical cell systems having a degassing...

    Office of Scientific and Technical Information (OSTI)

    Title: Lithium based electrochemical cell systems having a degassing agent A lithium based electrochemical cell system includes a positive electrode; a negative electrode; an ...

  1. Lithium-ion batteries with intrinsic pulse overcharge protection...

    Office of Scientific and Technical Information (OSTI)

    The present invention relates in general to the field of lithium rechargeable batteries, and more particularly relates to the positive electrode design of lithium-ion batteries ...

  2. Correlation of Lithium-Ion Battery Performance with Structural...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Correlation of Lithium-Ion Battery Performance with Structural and Chemical ... Specifically, the surfaces of lithium-ion battery electrodes evolve simultaneously with ...

  3. Lithium-Ion Battery Recycling Issues | Department of Energy

    Energy.gov [DOE] (indexed site)

    International Collaboration With a Case Study in Assessment of Worlds Supply of Lithium Vehicle Technologies Office Merit Review 2015: Lithium-Ion Battery Production and ...

  4. Electrolyte additive for lithium rechargeable organic electrolyte battery

    DOEpatents

    Behl, Wishvender K.; Chin, Der-Tau

    1989-01-01

    A large excess of lithium iodide in solution is used as an electrolyte adive to provide overcharge protection for a lithium rechargeable organic electrolyte battery.

  5. Designing Silicon Nanostructures for High Energy Lithium Ion...

    Energy.gov [DOE] (indexed site)

    Performance Lithium-ion Battery Anodes Vehicle Technologies Office Merit Review 2014: Wiring Up Silicon Nanostructures for High Energy Lithium-Ion Battery Anodes Vehicle ...

  6. Overcoming Processing Cost Barriers of High-Performance Lithium...

    Energy.gov [DOE] (indexed site)

    Lithium-Ion Battery Electrodes Vehicle Technologies Office Merit Review 2014: Overcoming Processing Cost Barriers of High-Performance Lithium-Ion Battery Electrodes ...

  7. Water-lithium bromide double-effect absorption cooling analysis...

    Office of Scientific and Technical Information (OSTI)

    Water-lithium bromide double-effect absorption cooling analysis Citation Details In-Document Search Title: Water-lithium bromide double-effect absorption cooling analysis You ...

  8. Fact Sheet: Lithium-Ion Batteries for Stationary Energy Storage...

    Office of Environmental Management (EM)

    Lithium-Ion Batteries for Stationary Energy Storage (October 2012) Fact Sheet: Lithium-Ion Batteries for Stationary Energy Storage (October 2012) DOE's Energy Storage Program is ...

  9. Vehicle Technologies Office Merit Review 2014: High Energy Lithium...

    Office of Environmental Management (EM)

    High Energy Lithium Batteries for PHEV Applications Vehicle Technologies Office Merit Review 2014: High Energy Lithium Batteries for PHEV Applications Presentation given by...

  10. Inexpensive, Nonfluorinated Anions for Lithium Salts and Ionic...

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    Electrolytes Inexpensive, Nonfluorinated Anions for Lithium Salts and Ionic Liquids for Lithium Battery Electrolytes 2010 DOE Vehicle Technologies and Hydrogen Programs Annual...

  11. China Lithium Energy Electric Vehicle Investment Group CLEEVIG...

    OpenEI (Open Energy Information) [EERE & EIA]

    Lithium Energy Electric Vehicle Investment Group CLEEVIG Jump to: navigation, search Name: China Lithium Energy Electric Vehicle Investment Group (CLEEVIG) Place: Beijing, China...

  12. Electrolyte additive for lithium rechargeable organic electrolyte battery

    DOEpatents

    Behl, Wishvender K.; Chin, Der-Tau

    1989-02-07

    A large excess of lithium iodide in solution is used as an electrolyte adive to provide overcharge protection for a lithium rechargeable organic electrolyte battery.

  13. Composite Electrodes for Rechargeable Lithium-Ion Batteries ...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Composite Electrodes for Rechargeable Lithium-Ion Batteries Technology available for ... of lithium layers by transition metal ions. PDF icon compositeelectrodesforlibatteries

  14. Scientists Probe Lithium-Sulfur Batteries in Real Time - Joint...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    7, 2012, Videos Scientists Probe Lithium-Sulfur Batteries in Real Time Lithium-sulfur batteries are a promising technology that could some day power electric vehicles. Scientists ...

  15. Understanding Lithium-Sulfur Batteries at the Molecular Level...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    June 17, 2015, Accomplishments Understanding Lithium-Sulfur Batteries at the Molecular Level Conceived some 40 years ago, the lithium-sulfur battery can store, in theory, ...

  16. Surface Modification Agents Increase Safety, Security of Lithium...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Surface Modification Agents Increase Safety, Security of Lithium-Ion Batteries New Process to Modify the Surface of the Active Material Used in Lithium-Ion Batteries Argonne ...

  17. Nanocomposite Carbon/Tin Anodes for Lithium Ion Batteries - Energy...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Nanocomposite CarbonTin Anodes for Lithium Ion Batteries Lawrence Berkeley National ... Applications and Industries Anodes for lithium ion batteries More InformationFOR MORE ...

  18. Novel Electrolyte Enables Stable Graphite Anodes in Lithium Ion...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Novel Electrolyte Enables Stable Graphite Anodes in Lithium Ion Batteries Lawrence ... Coulombic Efficiency for Lithium Ion Batteries," Journal of the Electrochemical ...

  19. Longer Life Lithium Ion Batteries with Silicon Anodes - Energy...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Longer Life Lithium Ion Batteries with Silicon Anodes Lawrence Berkeley National ... Researchers have developed a new technology to advance the life of lithium-ion batteries. ...

  20. Lithium Metal Oxide Electrodes For Lithium Cells And Batteries

    DOEpatents

    Thackeray, Michael M.; Johnson, Christopher S.; Amine, Khalil; Kim, Jaekook

    2004-01-20

    A lithium metal oxide positive electrode for a non-aqueous lithium cell is disclosed. The cell is prepared in its initial discharged state and has a general formula xLiMO.sub.2.(1-x)Li.sub.2 M'O.sub.3 in which 0

  1. Lithium metal oxide electrodes for lithium cells and batteries

    DOEpatents

    Thackeray, Michael M.; Johnson, Christopher S.; Amine, Khalil

    2008-12-23

    A lithium metal oxide positive electrode for a non-aqueous lithium cell is disclosed. The cell is prepared in its initial discharged state and has a general formula xLiMO.sub.2.(1-x)Li.sub.2M'O.sub.3 in which 0

  2. Electrode materials and lithium battery systems

    DOEpatents

    Amine, Khalil; Belharouak, Ilias; Liu, Jun

    2011-06-28

    A material comprising a lithium titanate comprising a plurality of primary particles and secondary particles, wherein the average primary particle size is about 1 nm to about 500 nm and the average secondary particle size is about 1 .mu.m to about 4 .mu.m. In some embodiments the lithium titanate is carbon-coated. Also provided are methods of preparing lithium titanates, and devices using such materials.

  3. California Energy Incentive Programs

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    California Energy Incentive Programs: An Annual Update on Key Energy Issues and Financial Opportunities for Federal Sites in California Prepared for the U.S. Department of Energy Federal Energy Management Program December 2011 i Contacts Utility Acquisitions, ESPCs, PPAs Tracy Logan U.S. Department of Energy Federal Energy Management Program EE-2L 1000 Independence Avenue, SW Washington, DC 20585-0121 Phone: (202) 586-9973 E-mail: tracy.logan@ee.doe.gov Principal Research Associate Elizabeth

  4. California State Assembly | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Assembly Jump to: navigation, search Name: California State Assembly Place: Sacramento, California Zip: 94249-0000 Product: The body of the state of California that reviews bills,...

  5. BLM California State Office | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Office Jump to: navigation, search Logo: BLM California State Office Name: BLM California State Office Abbreviation: California Address: 2800 Cottage Way, Suite W-1623 Place:...

  6. California Energy Power | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Power Jump to: navigation, search Name: California Energy & Power Place: Pomona, California Zip: CA 91767 Sector: Renewable Energy, Wind energy Product: California Energy & Power...

  7. California's 38th congressional district: Energy Resources |...

    OpenEI (Open Energy Information) [EERE & EIA]

    can help OpenEI by expanding it. This page represents a congressional district in California. Registered Energy Companies in California's 38th congressional district California...

  8. California Air Resources Board | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Air Resources Board Jump to: navigation, search Logo: California Air Resources Board Name: California Air Resources Board Place: Sacramento, California Website: www.arb.ca.gov...

  9. Marathon Capital LLC (California) | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Marathon Capital LLC (California) Name: Marathon Capital LLC (California) Address: 42 Miller Avenue Place: Mill Valley, California Zip: 94941 Region: Bay Area Product: Investment...

  10. Northern California Power Agny | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    California Power Agny Jump to: navigation, search Name: Northern California Power Agny Place: California Website: www.ncpa.com Outage Hotline: (916) 781-3636 References: EIA Form...

  11. Delano, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    expanding it. Delano is a city in Kern County, California. It falls under California's 20th congressional district.12 Energy Generation Facilities in Delano, California Delano...

  12. Mendota, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    it. Mendota is a city in Fresno County, California. It falls under California's 20th congressional district.12 Energy Generation Facilities in Mendota, California...

  13. Bakersfield, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    it. Bakersfield is a city in Kern County, California. It falls under California's 20th congressional district and California's 22nd congressional district.12 Registered...

  14. California Independent System Operator | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    search 200px Name: California Independent System Operator Address: California ISO P.O. Box 639014 Place: Folsom, California Zip: 95763-9014 Sector: Services Phone Number:...

  15. Understanding the Ultimate Battery Chemistry: Rechargeable Lithium...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Kah Chun Lau (MSD, ANL), Aaron Knoll (MCS, ANL), Larry A Curtiss (MSDCNM, ANL). Understanding the Ultimate Battery Chemistry: Rechargeable LithiumAir PI Name: Jack Wells PI ...

  16. Ternary compound electrode for lithium cells

    DOEpatents

    Raistrick, I.D.; Godshall, N.A.; Huggins, R.A.

    1980-07-30

    Lithium-based cells are promising for applications such as electric vehicles and load-leveling for power plants since lithium is very electropositive and of light weight. One type of lithium-based cell utilizes a molten salt electrolyte and normally is operated in the temperature range of about 350 to 500/sup 0/C. Such high temperature operation accelerates corrosion problems. The present invention provides an electrochemical cell in which lithium is the electroactive species. The cell has a positive electrode which includes a ternary compound generally represented as Li-M-O, wherein M is a transition metal. Corrosion of the inventive cell is considerably reduced.

  17. Ternary compound electrode for lithium cells

    DOEpatents

    Raistrick, Ian D.; Godshall, Ned A.; Huggins, Robert A.

    1982-01-01

    Lithium-based cells are promising for applications such as electric vehicles and load-leveling for power plants since lithium is very electropositive and of light weight. One type of lithium-based cell utilizes a molten salt electrolyte and normally is operated in the temperature range of about 350.degree.-500.degree. C. Such high temperature operation accelerates corrosion problems. The present invention provides an electrochemical cell in which lithium is the electroactive species. The cell has a positive electrode which includes a ternary compound generally represented as Li-M-O, wherein M is a transition metal. Corrosion of the inventive cell is considerably reduced.

  18. Simplified Electrode Formation using Stabilized Lithium Metal...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Metal Powder (SLMP) Doping of Lithium Ion Battery Electrodes Lawrence Berkeley National Laboratory Contact LBL About This Technology Technology Marketing Summary A team of ...

  19. Lithium Metal Anodes for Rechargeable Batteries

    SciTech Connect

    Xu, Wu; Wang, Jiulin; Ding, Fei; Chen, Xilin; Nasybulin, Eduard N.; Zhang, Yaohui; Zhang, Jiguang

    2013-10-29

    Rechargeable lithium metal batteries have much higher energy density than those of lithium ion batteries using graphite anode. Unfortunately, uncontrollable dendritic lithium growth inherent in these batteries (upon repeated charge/discharge cycling) and limited Coulombic efficiency during lithium deposition/striping has prevented their practical application over the past 40 years. With the emerging of post Li-ion batteries, safe and efficient operation of lithium metal anode has become an enabling technology which may determine the fate of several promising candidates for the next generation of energy storage systems, including rechargeable Li-air battery, Li-S battery, and Li metal battery which utilize lithium intercalation compounds as cathode. In this work, various factors which affect the morphology and Coulombic efficiency of lithium anode will be analyzed. Technologies used to characterize the morphology of lithium deposition and the results obtained by modeling of lithium dendrite growth will also be reviewed. At last, recent development in this filed and urgent need in this field will also be discussed.

  20. Structural Interactions within Lithium Salt Solvates: Cyclic...

    Office of Scientific and Technical Information (OSTI)

    and ester solvents coordinate Li+ cations in electrolyte solutions for lithium batteries. One approach to gleaning significant insight into these interactions is to examine...

  1. Categorical Exclusion 4497: Lithium Wet Chemistry Project

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Department of Energy Categorical Exclusion Detennination Form Proposed Action Tills: Lithium W@t Chemistry Project (4597) Program or Fild Oftke: Y-12 Site Office L&cationfs)...

  2. Categorical Exclusion 4577: Lithium Isotope Separation & Enrichment...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Lithium Isotope Separation & Enrichment Technologies (4577) Program or Field Office: Y-12 Site Office Location(s) (CityCountyState): Oak Ridge, Anderson County, Tennessee...

  3. ELECTROCHROMIC NICKEL OXIDE SIMULTANEOUSLY DOPED WITH LITHIUM...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    News Events Return to Search ELECTROCHROMIC NICKEL OXIDE SIMULTANEOUSLY DOPED WITH LITHIUM AND A METAL DOPANT United States Patent Application *** PATENT GRANTED ***...

  4. Lithium electrodeposition dynamics in aprotic electrolyte observed...

    Office of Scientific and Technical Information (OSTI)

    Citation Details In-Document Search Title: Lithium electrodeposition dynamics in aprotic ... the Li plating and stripping processes is needed to enable practical Li-metal batteries. ...

  5. Electronic Spin Transition in Nanosize Stoichiometric Lithium...

    Office of Scientific and Technical Information (OSTI)

    Title: Electronic Spin Transition in Nanosize Stoichiometric Lithium Cobalt Oxide Authors: ... Language: English Subject: energy storage (including batteries and capacitors), defects, ...

  6. Conductive polymeric compositions for lithium batteries (Patent...

    Office of Scientific and Technical Information (OSTI)

    The conductivity at high temperatures and wide electrochemical window make these materials especially suitable as electrolytes for rechargeable lithium batteries. Inventors: ...

  7. Washington: Graphene Nanostructures for Lithium Batteries Recieves...

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    Graphene Nanostructures for Lithium Batteries Recieves 2012 R&D 100 Award Washington: ... Improving charge time and these other battery characteristics could significantly expand ...

  8. Iron-lithium anode for thermal battery

    SciTech Connect

    Winchester, C.S.

    1987-06-23

    This patent describes a lithium anode for use in a thermal battery having a composite material comprising lithium and a particulate metal capable of being wetted by molten lithium, but only slightly or not alloyable with the lithium. The composite anode material is positioned adjacent a metal collector element the improvement comprising: a metal screen positioned between and substantially co-extensive with the anode composite and the metal collector element. The anode is thereby spaced apart from the element but is in electrical contact and the screen is electrically conductive.

  9. Neutronics Evaluation of Lithium-Based Ternary Alloys in IFE Blankets

    SciTech Connect

    Jolodosky, A.; Fratoni, M.

    2015-09-22

    , low electrical conductivity and therefore low MHD pressure drop, low chemical reactivity, and extremely low tritium inventory; the addition of sodium (FLiNaBe) has been considered because it retains the properties of FliBe but also lowers the melting point. Although many of these blanket concepts are promising, challenges still remain. The limited amount of beryllium available poses a problem for ceramic breeders such as the HCPB. FLiBe and FLiNaBe are highly viscous and have a low thermal conductivity. Lithium lead possesses a poor thermal conductivity which can cause problems in both DCLL and LiPb blankets. Additionally, the tritium permeation from these two blankets into plant components can be a problem and must be reduced. Consequently, Lawrence Livermore National Laboratory (LLNL) is attempting to develop a lithium-based alloy—most likely a ternary alloy—which maintains the beneficial properties of lithium (e.g. high tritium breeding and solubility) while reducing overall flammability concerns for use in the blanket of an inertial fusion energy (IFE) power plant. The LLNL concept employs inertial confinement fusion (ICF) through the use of lasers aimed at an indirect-driven target composed of deuterium-tritium fuel. The fusion driver/target design implements the same physics currently experimented at the National Ignition Facility (NIF). The plant uses lithium in both the primary coolant and blanket; therefore, lithium-related hazards are of primary concern. Although reducing chemical reactivity is the primary motivation for the development of new lithium alloys, the successful candidates will have to guarantee acceptable performance in all their functions. The scope of this study is to evaluate the neutronics performance of a large number of lithium-based alloys in the blanket of the IFE engine and assess their properties upon activation. This manuscript is organized as follows: Section 12 presents the models and methodologies used for the analysis; Section

  10. Electrolytes for lithium ion batteries

    DOEpatents

    Vaughey, John; Jansen, Andrew N.; Dees, Dennis W.

    2014-08-05

    A family of electrolytes for use in a lithium ion battery. The genus of electrolytes includes ketone-based solvents, such as, 2,4-dimethyl-3-pentanone; 3,3-dimethyl 2-butanone(pinacolone) and 2-butanone. These solvents can be used in combination with non-Lewis Acid salts, such as Li.sub.2[B.sub.12F.sub.12] and LiBOB.

  11. A lithium oxygen secondary battery

    SciTech Connect

    Semkow, K.W.; Sammells, A.F.

    1987-08-01

    In principle the lithium-oxygen couple should provide one of the highest energy densities yet investigated for advanced battery systems. The problem to this time has been one of identifying strategies for achieving high electrochemical reversibilities at each electrode under conditions where one might anticipate to also achieve long materials lifetimes. This has been addressed in recent work by us via the application of stabilized zirconia oxygen vacancy conducting solid electrolytes, for the effective separation of respective half-cell reactions.

  12. Solid polymer electrolyte lithium batteries

    DOEpatents

    Alamgir, M.; Abraham, K.M.

    1993-10-12

    This invention pertains to Lithium batteries using Li ion (Li[sup +]) conductive solid polymer electrolytes composed of solvates of Li salts immobilized in a solid organic polymer matrix. In particular, this invention relates to Li batteries using solid polymer electrolytes derived by immobilizing solvates formed between a Li salt and an aprotic organic solvent (or mixture of such solvents) in poly(vinyl chloride). 3 figures.

  13. Solid polymer electrolyte lithium batteries

    DOEpatents

    Alamgir, Mohamed; Abraham, Kuzhikalail M.

    1993-01-01

    This invention pertains to Lithium batteries using Li ion (Li.sup.+) conductive solid polymer electrolytes composed of solvates of Li salts immobilized in a solid organic polymer matrix. In particular, this invention relates to Li batteries using solid polymer electrolytes derived by immobilizing solvates formed between a Li salt and an aprotic organic solvent (or mixture of such solvents) in poly(vinyl chloride).

  14. NANOWIRE CATHODE MATERIAL FOR LITHIUM-ION BATTERIES

    SciTech Connect

    John Olson, PhD

    2004-07-21

    -power lithium-ion battery cathode needed for advanced EV and HEVs. Several technical advancements will still be required to meet this goal, and are likely topics for future SBIR feasibility studies.

  15. Secretary Chu's Remarks at the California Institute of Technology

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    Commencement - As Prepared for Delivery | Department of Energy California Institute of Technology Commencement - As Prepared for Delivery Secretary Chu's Remarks at the California Institute of Technology Commencement - As Prepared for Delivery June 12, 2009 - 12:00am Addthis Before I begin, I want to offer my deepest condolences to the family and friends of Brian Go and Jackson Wang and to the entire Caltech community. Tragedies like this touch us all. President Chameau, trustees, faculty,

  16. Jeff Chamberlain on Lithium-air batteries

    SciTech Connect

    Chamberlain, Jeff

    2009-01-01

    Jeff Chamberlain, technology transfer expert at Argonne National Laboratory, speaks on the new technology Lithium-air batteries, which could potentially increase energy density by 5-10 times over lithium-ion batteries. More information at http://www.anl.gov/Media_Center/News/2009/batteries090915.html

  17. Jeff Chamberlain on Lithium-air batteries

    ScienceCinema

    Chamberlain, Jeff

    2013-04-19

    Jeff Chamberlain, technology transfer expert at Argonne National Laboratory, speaks on the new technology Lithium-air batteries, which could potentially increase energy density by 5-10 times over lithium-ion batteries. More information at http://www.anl.gov/Media_Center/News/2009/batteries090915.html

  18. California: California's Clean Energy Resources and Economy (Brochure)

    SciTech Connect

    Not Available

    2013-03-01

    This document highlights the Office of Energy Efficiency and Renewable Energy's investments and impacts in the state of California.

  19. Jiangsu-California MOU | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    California MOU AgencyCompany Organization Jiangsu, State of California Sector Energy Focus Area Energy Efficiency, Transportation Topics Policiesdeployment programs...

  20. California Hydrogen Infrastructure Project | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Hydrogen Infrastructure Project Jump to: navigation, search Name: California Hydrogen Infrastructure Project Place: California Sector: Hydro, Hydrogen Product: String...

  1. California Sunrise Alternative Energy Development LLC | Open...

    OpenEI (Open Energy Information) [EERE & EIA]

    Zip: 93505 Sector: Services Product: String representation "California Sunr ... g and lighting." is too long. References: California Sunrise Alternative Energy...

  2. 2015 Market Research Report on Global Niobium Oxalate Lithium...

    OpenEI (Open Energy Information) [EERE & EIA]

    Niobium Oxalate Lithium Industry Home There are currently no posts in this category. Syndicate content...

  3. Impact of Lithium Availability on Vehicle Electrification (Presentation)

    SciTech Connect

    Neubauer, J.

    2011-07-01

    This presentation discusses the relationship between electric drive vehicles and the availability of lithium.

  4. Lithium ion batteries based on nanoporous silicon

    SciTech Connect

    Tolbert, Sarah H.; Nemanick, Eric J.; Kang, Chris Byung-Hwa

    2015-09-22

    A lithium ion battery that incorporates an anode formed from a Group IV semiconductor material such as porous silicon is disclosed. The battery includes a cathode, and an anode comprising porous silicon. In some embodiments, the anode is present in the form of a nanowire, a film, or a powder, the porous silicon having a pore diameters within the range between 2 nm and 100 nm and an average wall thickness of within the range between 1 nm and 100 nm. The lithium ion battery further includes, in some embodiments, a non-aqueous lithium containing electrolyte. Lithium ion batteries incorporating a porous silicon anode demonstrate have high, stable lithium alloying capacity over many cycles.

  5. California Solar Initiative- PV Incentives

    Energy.gov [DOE]

    In January 2006, the California Public Utilities Commission (CPUC) adopted a program -- the California Solar Initiative (CSI) -- to provide more than $2.3 billion in incentives for photovoltaic (...

  6. Electrolyte additive for lithium rechargeable organic electrolyte battery

    SciTech Connect

    Behl, W.K.; Chin, D.T.

    1988-02-08

    This invention relates in general to a rechargeable lithium organic electrolyte battery and, in particular, to an electrolyte additive for such a battery that provides overcharge protection. Rechargeable lithium-organic electrolyte batteries are being developed to provide low-cost, high-energy-density power sources for communication, night vision and various other Army applications. Typically, a rechargeable lithium organic electrolyte battery includes a lithium anode, a cathode including compounds such as titanium disulfide, molybdenum oxide, molybdenum sulfide, vanadium oxide, vanadium sulfide, chromium oxide, etc an electrolyte solution including an inorganic lithium salt such as lithium hexafluoroarsenate, lithium perchlorate, etc.

  7. Oxnard, California, Site Fact Sheet

    Office of Legacy Management (LM)

    Oxnard, California, Site This fact sheet provides information about the Oxnard, California, Site. The U.S. Department of Energy Office of Legacy Management manages historical records of work performed for the federal government at the Oxnard site. Location of the Oxnard, California, Site Site Description and History The Oxnard site occupies 13.75 acres in an industrial section of Oxnard, California, about 50 miles northwest of Los Angeles. Allis-Chalmers, a farm implement manufacturing company,

  8. Process for recovering tritium from molten lithium metal

    DOEpatents

    Maroni, Victor A.

    1976-01-01

    Lithium tritide (LiT) is extracted from molten lithium metal that has been exposed to neutron irradiation for breeding tritium within a thermonuclear or fission reactor. The extraction is performed by intimately contacting the molten lithium metal with a molten lithium salt, for instance, lithium chloride - potassium chloride eutectic to distribute LiT between the salt and metal phases. The extracted tritium is recovered in gaseous form from the molten salt phase by a subsequent electrolytic or oxidation step.

  9. Trace Water Catalyzes Lithium Peroxide Electrochemistry - Joint Center for

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Energy Storage Research June 19, 2014, Research Highlights Trace Water Catalyzes Lithium Peroxide Electrochemistry Reaction cycle for reduction of di-oxygen by lithium and water to lithium peroxide on single crystal gold surface. Scientific Achievement Water at ppm levels catalyzes the conversion of lithium superoxide (LiO2) to lithium peroxide (Li2O2) by the reaction cycle shown. Because water is not consumed in the cycle, trace amounts leverage large effects. Significance and Impact Trace

  10. Electroactive compositions with poly(arylene oxide) and stabilized lithium

    Office of Scientific and Technical Information (OSTI)

    metal particles (Patent) | DOEPatents Electroactive compositions with poly(arylene oxide) and stabilized lithium metal particles Title: Electroactive compositions with poly(arylene oxide) and stabilized lithium metal particles An electroactive composition includes an anodic material; a poly(arylene oxide); and stabilized lithium metal particles; where the stabilized lithium metal particles have a size less than about 200 .mu.m in diameter, are coated with a lithium salt, are present in an

  11. LithiumIonBatteries.jpg | OSTI, US Dept of Energy Office of Scientific and

    Office of Scientific and Technical Information (OSTI)

    Technical Information LithiumIonBatteries

  12. Carbons for lithium batteries prepared using sepiolite as an inorganic template

    DOEpatents

    Sandi, Giselle (Wheaton, IL); Winans, Randall E. (Downers Grove, IL); Gregar, K. Carrado (Naperville, IL)

    2000-01-01

    A method of preparing an anode material using sepiolite clay having channel-like interstices in its lattice structure. Carbonaceous material is deposited in the channel-like interstices of the sepiolite clay and then the sepiolite clay is removed leaving the carbonaceous material. The carbonaceous material is formed into an anode. The anode is combined with suitable cathode and electrolyte materials to form a battery of the lithium-ion type.

  13. Lithium thermal targets shot on PBFA II

    SciTech Connect

    Sawyer, P.S.; Aubert, J.H.; Baca, P.M.; McNamara, W.F.

    1993-09-01

    Recent lithium ion beam experiments on PBFAII have required intricate targets to measure beam performance and to study target physics issues. Because of the stopping power difference between lithium ions and protons, these targets have presented significantly increased challenges for material preparation and handling compared to previous proton shots. The greatest challenges included complex shaped gold hohlraums, CH foams of densities ranging from 3 to 6 mg/cm3 and vacuum seals covering large areas with a thickness under 1 um. Details regarding assembly and characterization of lithium thermal targets will be described in this poster.

  14. Modeling Lithium Movement over Multiple Cycles in a Lithium-Metal Battery

    SciTech Connect

    Ferrese, A; Newman, J

    2014-04-11

    This paper builds on the work by Ferrese et al. [J. Electrochem., 159, A1615 (2012)], where a model of a lithium-metal battery with a LiyCoO2 positive electrode was created in order to predict the movement of lithium in the negative electrode along the negative electrode/separator interface during cell cycling. In this paper, the model is expanded to study the movement of lithium along the lithium-metal anode over multiple cycles. From this model, it is found that when a low percentage of lithium at the negative electrode is utilized, the movement of lithium along the negative electrode/separator interface reaches a quasi steady state after multiple cycles. This steady state is affected by the slope of the open-circuit-potential function in the positive electrode, the rate of charge and discharge, the depth of discharge, and the length of the rest periods. However, when a high percent of the lithium at the negative electrode is utilized during cycling, the movement does not reach a steady state and pinching can occur, where the lithium nearest the negative tab becomes progressively thinner after cycling. This is another nonlinearity that leads to a progression of the movement of lithium over multiple cycles. (C) 2014 The Electrochemical Society.

  15. Electrolytic method for the production of lithium using a lithium-amalgam electrode

    DOEpatents

    Cooper, John F.; Krikorian, Oscar H.; Homsy, Robert V.

    1979-01-01

    A method for recovering lithium from its molten amalgam by electrolysis of the amalgam in an electrolytic cell containing as a molten electrolyte a fused-salt consisting essentially of a mixture of two or more alkali metal halides, preferably alkali metal halides selected from lithium iodide, lithium chloride, potassium iodide and potassium chloride. A particularly suitable molten electrolyte is a fused-salt consisting essentially of a mixture of at least three components obtained by modifying an eutectic mixture of LiI-KI by the addition of a minor amount of one or more alkali metal halides. The lithium-amalgam fused-salt cell may be used in an electrolytic system for recovering lithium from an aqueous solution of a lithium compound, wherein electrolysis of the aqueous solution in an aqueous cell in the presence of a mercury cathode produces a lithium amalgam. The present method is particularly useful for the regeneration of lithium from the aqueous reaction products of a lithium-water-air battery.

  16. California/Transmission/Agency Links | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    State Agency Links California Department of Fish and Wildlife California Office of Historic Preservation California Department of Transportation California Department of...

  17. California Climate Exchange CaCX | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    CaCX Jump to: navigation, search Name: California Climate Exchange (CaCX) Place: California Product: Aims to reducte CO2 emission in California. References: California Climate...

  18. EIS-0431: Hydrogen Energy California's Project, Kern County,...

    Energy Saver

    31: Hydrogen Energy California's Project, Kern County, California EIS-0431: Hydrogen Energy California's Project, Kern County, California Summary This EIS evaluates the potential...

  19. NSTX Plasma Response to Lithium Coated Divertor

    SciTech Connect

    H.W. Kugel, M.G. Bell, J.P. Allain, R.E. Bell, S. Ding, S.P. Gerhardt, M.A. Jaworski, R. Kaita, J. Kallman, S.M. Kaye, B.P. LeBlanc, R. Maingi, R. Majeski, R. Maqueda, D.K. Mansfield, D. Mueller, R. Nygren, S.F. Paul, R. Raman, A.L. Roquemore, S.A. Sabbagh, H. Schneider, C.H. Skinner, V.A. Soukhanovskii, C.N. Taylor, J.R. Timberlak, W.R. Wampler, L.E. Zakharov, S.J. Zweben, and the NSTX Research Team

    2011-01-21

    NSTX experiments have explored lithium evaporated on a graphite divertor and other plasma facing components in both L- and H- mode confinement regimes heated by high-power neutral beams. Improvements in plasma performance have followed these lithium depositions, including a reduction and eventual elimination of the HeGDC time between discharges, reduced edge neutral density, reduced plasma density, particularly in the edge and the SOL, increased pedestal electron and ion temperature, improved energy confinement and the suppression of ELMs in the H-mode. However, with improvements in confinement and suppression of ELMs, there was a significant secular increase in the effective ion charge Zeff and the radiated power in H-mode plasmas as a result of increases in the carbon and medium-Z metallic impurities. Lithium itself remained at a very low level in the plasma core, <0.1%. Initial results are reported from operation with a Liquid Lithium Divertor (LLD) recently installed.

  20. Lithium Circuit Test Section Design and Fabrication

    SciTech Connect

    Godfroy, Thomas; Garber, Anne; Martin, James

    2006-01-20

    The Early Flight Fission -- Test Facilities (EFF-TF) team has designed and built an actively pumped lithium flow circuit. Modifications were made to a circuit originally designed for NaK to enable the use of lithium that included application specific instrumentation and hardware. Component scale freeze/thaw tests were conducted to both gain experience with handling and behavior of lithium in solid and liquid form and to supply anchor data for a Generalized Fluid System Simulation Program (GFSSP) model that was modified to include the physics for freeze/thaw transitions. Void formation was investigated. The basic circuit components include: reactor segment, lithium to gas heat exchanger, electromagnetic (EM) liquid metal pump, load/drain reservoir, expansion reservoir, instrumentation, and trace heaters. This paper discusses the overall system design and build and the component testing findings.

  1. Y-12 begins to separate lithium isotopes

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    begins to separate lithium isotopes During the years from 1946 through the early 1950s, Y-12 continued to expand as needed to meet the demand for a growing primary mission of...

  2. Shock Induced Birefringence in Lithium Fluoride

    SciTech Connect

    Holmes, N C

    2001-06-01

    We have used an ellipsometer to measure the birefringence of lithium fluoride in shock compression experiments. In previous x-ray diffraction experiments, single crystal [100] LiF has been reported to remain cubic at moderate pressures.

  3. Lithium Metal Anodes | Department of Energy

    Energy.gov [DOE] (indexed site)

    esp17vaughey.pdf (3.6 MB) More Documents & Publications Lithium Metal Anodes Integrated LabIndustry Research Project at LBNL Overview and Progress of the Exploratory Technology ...

  4. Lithium ion battery with improved safety

    DOEpatents

    Chen, Chun-hua; Hyung, Yoo Eup; Vissers, Donald R.; Amine, Khalil

    2006-04-11

    A lithium battery with improved safety that utilizes one or more additives in the battery electrolyte solution wherein a lithium salt is dissolved in an organic solvent, which may contain propylene, carbonate. For example, a blend of 2 wt % triphenyl phosphate (TPP), 1 wt % diphenyl monobutyl phosphate (DMP) and 2 wt % vinyl ethylene carbonate additives has been found to significantly enhance the safety and performance of Li-ion batteries using a LiPF6 salt in EC/DEC electrolyte solvent. The invention relates to both the use of individual additives and to blends of additives such as that shown in the above example at concentrations of 1 to 4-wt % in the lithium battery electrolyte. This invention relates to additives that suppress gas evolution in the cell, passivate graphite electrode and protect it from exfoliating in the presence of propylene carbonate solvents in the electrolyte, and retard flames in the lithium batteries.

  5. Cathode material for lithium batteries (Patent) | DOEPatents

    Office of Scientific and Technical Information (OSTI)

    The mixture is thermally treated to obtain the lithium molybdenum composite transition metal oxide cathode material. Inventors: Park, Sang-Ho ; Amine, Khalil Issue Date: 2015-01-13 ...

  6. Layered electrodes for lithium cells and batteries

    DOEpatents

    Johnson, Christopher S.; Thackeray, Michael M.; Vaughey, John T.; Kahaian, Arthur J.; Kim, Jeom-Soo

    2008-04-15

    Lithium metal oxide compounds of nominal formula Li.sub.2MO.sub.2, in which M represents two or more positively charged metal ions, selected predominantly and preferably from the first row of transition metals are disclosed herein. The Li.sub.2MO.sub.2 compounds have a layered-type structure, which can be used as positive electrodes for lithium electrochemical cells, or as a precursor for the in-situ electrochemical fabrication of LiMO.sub.2 electrodes. The Li.sub.2MO.sub.2 compounds of the invention may have additional functions in lithium cells, for example, as end-of-discharge indicators, or as negative electrodes for lithium cells.

  7. Design and simulation of lithium rechargeable batteries

    SciTech Connect

    Doyle, C.M.

    1995-08-01

    Lithium -based rechargeable batteries that utilize insertion electrodes are being considered for electric-vehicle applications because of their high energy density and inherent reversibility. General mathematical models are developed that apply to a wide range of lithium-based systems, including the recently commercialized lithium-ion cell. The modeling approach is macroscopic, using porous electrode theory to treat the composite insertion electrodes and concentrated solution theory to describe the transport processes in the solution phase. The insertion process itself is treated with a charge-transfer process at the surface obeying Butler-Volmer kinetics, followed by diffusion of the lithium ion into the host structure. These models are used to explore the phenomena that occur inside of lithium cells under conditions of discharge, charge, and during periods of relaxation. Also, in order to understand the phenomena that limit the high-rate discharge of these systems, we focus on the modeling of a particular system with well-characterized material properties and system parameters. The system chosen is a lithium-ion cell produced by Bellcore in Red Bank, NJ, consisting of a lithium-carbon negative electrode, a plasticized polymer electrolyte, and a lithium-manganese-oxide spinel positive electrode. This battery is being marketed for consumer electronic applications. The system is characterized experimentally in terms of its transport and thermodynamic properties, followed by detailed comparisons of simulation results with experimental discharge curves. Next, the optimization of this system for particular applications is explored based on Ragone plots of the specific energy versus average specific power provided by various designs.

  8. Nanocomposite Materials for Lithium-Ion Batteries

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    Nanocomposite Materials for Lithium-Ion Batteries Development and Application of Processing and Process Control for Nanocomposite Materials for Lithium-Ion Batteries Introduction In recent years, sales of hybrid electric vehicles (HEVs) have increased and several automakers have also started to market plug-in hybrid electric vehicles (PHEVs). Successful market penetration of PHEVs would signifcantly reduce automobile tailpipe emissions and help guard against oil price volatility. However, cost,

  9. Rechargeable Thin-film Lithium Batteries

    DOE R&D Accomplishments

    Bates, J. B.; Gruzalski, G. R.; Dudney, N. J.; Luck, C. F.; Yu, Xiaohua

    1993-08-01

    Rechargeable thin film batteries consisting of lithium metal anodes, an amorphous inorganic electrolyte, and cathodes of lithium intercalation compounds have recently been developed. The batteries, which are typically less than 6 {mu}m thick, can be fabricated to any specified size, large or small, onto a variety of substrates including ceramics, semiconductors, and plastics. The cells that have been investigated include Li TiS{sub 2}, Li V{sub 2}O{sub 5}, and Li Li{sub x}Mn{sub 2}O{sub 4}, with open circuit voltages at full charge of about 2.5, 3.6, and 4.2, respectively. The development of these batteries would not have been possible without the discovery of a new thin film lithium electrolyte, lithium phosphorus oxynitride, that is stable in contact with metallic lithium at these potentials. Deposited by rf magnetron sputtering of Li{sub 3}PO{sub 4} in N{sub 2}, this material has a typical composition of Li{sub 2.9}PO{sub 3.3}N{sub 0.46} and a conductivity at 25{degrees}C of 2 {mu}S/cm. The maximum practical current density obtained from the thin film cells is limited to about 100 {mu}A/cm{sup 2} due to a low diffusivity of Li{sup +} ions in the cathodes. In this work, the authors present a short review of their work on rechargeable thin film lithium batteries.

  10. California City, California: Energy Resources | Open Energy Informatio...

    OpenEI (Open Energy Information) [EERE & EIA]

    City, California: Energy Resources Jump to: navigation, search Equivalent URI DBpedia Coordinates 35.125801, -117.9859038 Show Map Loading map... "minzoom":false,"mappingservi...

  11. California Offshore Natural Gas Processed in California (Million Cubic

    Energy Information Administration (EIA) (indexed site)

    Feet) Offshore Natural Gas Processed in California (Million Cubic Feet) California Offshore Natural Gas Processed in California (Million Cubic Feet) Decade Year-0 Year-1 Year-2 Year-3 Year-4 Year-5 Year-6 Year-7 Year-8 Year-9 2010's NA 381 174 - = No Data Reported; -- = Not Applicable; NA = Not Available; W = Withheld to avoid disclosure of individual company data. Release Date: 10/31/2016 Next Release Date: 11/30/2016 Referring Pages: Natural Gas Processed California Offshore

  12. California Onshore Natural Gas Processed in California (Million Cubic Feet)

    Energy Information Administration (EIA) (indexed site)

    Onshore Natural Gas Processed in California (Million Cubic Feet) California Onshore Natural Gas Processed in California (Million Cubic Feet) Decade Year-0 Year-1 Year-2 Year-3 Year-4 Year-5 Year-6 Year-7 Year-8 Year-9 2010's 180,648 169,203 164,401 162,413 143,732 - = No Data Reported; -- = Not Applicable; NA = Not Available; W = Withheld to avoid disclosure of individual company data. Release Date: 10/31/2016 Next Release Date: 11/30/2016 Referring Pages: Natural Gas Processed California

  13. Predissociation dynamics of lithium iodide

    SciTech Connect

    Schmidt, H.; Vangerow, J. von; Stienkemeier, F.; Mudrich, M.; Bogomolov, A. S.; Baklanov, A. V.; Reich, D. M.; Skomorowski, W.; Koch, C. P.

    2015-01-28

    The predissociation dynamics of lithium iodide (LiI) in the first excited A-state is investigated for molecules in the gas phase and embedded in helium nanodroplets, using femtosecond pump-probe photoionization spectroscopy. In the gas phase, the transient Li{sup +} and LiI{sup +} ion signals feature damped oscillations due to the excitation and decay of a vibrational wave packet. Based on high-level ab initio calculations of the electronic structure of LiI and simulations of the wave packet dynamics, the exponential signal decay is found to result from predissociation predominantly at the lowest avoided X-A potential curve crossing, for which we infer a coupling constant V{sub XA} = 650(20) cm{sup −1}. The lack of a pump-probe delay dependence for the case of LiI embedded in helium nanodroplets indicates fast droplet-induced relaxation of the vibrational excitation.

  14. Electrode for a lithium cell

    DOEpatents

    Thackeray, Michael M.; Vaughey, John T.; Dees, Dennis W.

    2008-10-14

    This invention relates to a positive electrode for an electrochemical cell or battery, and to an electrochemical cell or battery; the invention relates more specifically to a positive electrode for a non-aqueous lithium cell or battery when the electrode is used therein. The positive electrode includes a composite metal oxide containing AgV.sub.3O.sub.8 as one component and one or more other components consisting of LiV.sub.3O.sub.8, Ag.sub.2V.sub.4O.sub.11, MnO.sub.2, CF.sub.x, AgF or Ag.sub.2O to increase the energy density of the cell, optionally in the presence of silver powder and/or silver foil to assist in current collection at the electrode and to improve the power capability of the cell or battery.

  15. Rechargeable lithium-ion cell

    DOEpatents

    Bechtold, Dieter; Bartke, Dietrich; Kramer, Peter; Kretzschmar, Reiner; Vollbert, Jurgen

    1999-01-01

    The invention relates to a rechargeable lithium-ion cell, a method for its manufacture, and its application. The cell is distinguished by the fact that it has a metallic housing (21) which is electrically insulated internally by two half shells (15), which cover electrode plates (8) and main output tabs (7) and are composed of a non-conductive material, where the metallic housing is electrically insulated externally by means of an insulation coating. The cell also has a bursting membrane (4) which, in its normal position, is located above the electrolyte level of the cell (1). In addition, the cell has a twisting protection (6) which extends over the entire surface of the cover (2) and provides centering and assembly functions for the electrode package, which comprises the electrode plates (8).

  16. Glass for sealing lithium cells

    DOEpatents

    Leedecke, C.J.

    1981-08-28

    Glass compositions resistant to corrosion by lithium cell electrolyte and having an expansion coefficient of 45 to 85 x 10/sup -70/C/sup -1/ have been made with SiO/sub 2/, 25 to 55% by weight; B/sub 2/O/sub 3/, 5 to 12%; Al/sub 2/O/sub 3/, 12 to 35%; CaO, 5 to 15%; MgO, 5 to 15%; SrO, 0 to 10%; and La/sub 2/O/sub 3/, 0 to 5%. Preferred compositions within that range contain 3 to 8% SrO and 0.5 to 2.5% La/sub 2/O/sub 3/.

  17. Sacramento, California | Department of Energy

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    Sacramento, California Sacramento, California Sacramento Better Buildings Program Location: Sacramento, California Seed Funding: $2,813,246 - a portion of Los Angeles County's $30 million funding Target Building Types: Residential (single-family, multifamily, low-income) and commercial Website: hpp.smud.org/neighborhood-approach Learn More: Facebook: SMUD Read SMUD's newsletter Read SMUD 2011 Annual Report Sacramento Ramps Up Energy Efficiency in Two Neighborhoods Since 2010, the Sacramento

  18. Berkeley, California, Site Fact Sheet

    Office of Legacy Management (LM)

    Berkeley, California, Site. This site is managed by the U.S. Department of Energy Office of Legacy Management under the Formerly Utilized Sites Remedial Action Program. Berkeley, California, Site San Francisco Bay San Pablo Bay San Francisco Bay Berkeley Concord Hayward Oakland San Francisco Vallejo 101 80 280 980 780 880 580 680 80 580 680 Berkeley Site M:\LTS\111\0001\10\S03049\S0304900.mxd smithw 09/16/2011 12:45:06 PM 0 5 10 Miles Sacramento CALIFORNIA Location of the Berkeley, California,

  19. California Nuclear Profile - Power Plants

    Energy Information Administration (EIA) (indexed site)

    California nuclear power plants, summer capacity and net generation, 2010" "Plant nametotal reactors","Summer capacity (mw)","Net generation (thousand mwh)","Share of State ...

  20. California Gasoline Price Study, 2003

    Reports and Publications

    2003-01-01

    This is the final report to Congressman Ose describing the factors driving California's spring 2003 gasoline price spike and the subsequent price increases in June and August.

  1. Anaheim, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    is a stub. You can help OpenEI by expanding it. Anaheim is a city in Orange County, California. It falls under California's 40th congressional district and California's 42nd...

  2. Development of Large Format Lithium Ion Cells with Higher Energy...

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    Large Format Lithium Ion Cells with Higher Energy Density Exceeding 500WhL Development of Large Format Lithium Ion Cells with Higher Energy Density Exceeding 500WhL 2012 DOE ...

  3. Two Studies Reveal Details of Lithium-Battery Function

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Two Studies Reveal Details of Lithium-Battery Function Print Our way of life is deeply ... As conventional lithium-ion batteries approach their theoretical energy-storage limits, ...

  4. A Method to Distill Hydrogen Isotopes from Lithium | Princeton...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    to Distill Hydrogen Isotopes from Lithium This white paper outlines a method for the removal of tritium and deuterium from liquid lithium. The method is based on rapid or flash ...

  5. "Stationary Flowing Liquid Lithium System For Pumping Out Atomic...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Lithium System For Pumping Out Atomic Hydrogen Isotopes and Ions" Leonid E. Zakharov and Charles Gentile The system is comprised of a stationary closed loop for liquid lithium flow ...

  6. Electrode Interface Dictates Oxygen Evolution from Lithium Peroxide...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    from Lithium Peroxide in Li-O2 Batteries Isolation of the charge reaction from the discharge in Li-O2 cells by utilizing electrodes prefilled with commercial lithium peroxide ...

  7. A Better Anode Design to Improve Lithium-Ion Batteries

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    A Better Anode Design to Improve Lithium-Ion Batteries Print Lithium-ion batteries are in ... 8.0.1 show a lower "lowest unoccupied molecular orbital" for the new Berkeley Lab ...

  8. A Better Anode Design to Improve Lithium-Ion Batteries

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    A Better Anode Design to Improve Lithium-Ion Batteries Print Lithium-ion batteries are in smart phones, laptops, most other consumer electronics, and the newest electric cars. Good...

  9. Vehicle Technologies Office Merit Review 2015: High Energy Lithium...

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    lithium-sulfur cathodes. PDF icon es230cui2015o.pdf More Documents & Publications Additives and Cathode Materials for High-Energy Lithium Sulfur Batteries Vehicle Technologies...

  10. Polyamidoamine Dendrimer-Based Binders for High-Loading Lithium...

    Office of Scientific and Technical Information (OSTI)

    Title: Polyamidoamine Dendrimer-Based Binders for High-Loading Lithium-Sulfur Battery Cathodes Lithium-sulfur (Li-S) batteries are regarded as one of the most promising candidates ...

  11. MultiLayer solid electrolyte for lithium thin film batteries...

    Office of Scientific and Technical Information (OSTI)

    Patent: MultiLayer solid electrolyte for lithium thin film batteries Citation Details In-Document Search Title: MultiLayer solid electrolyte for lithium thin film batteries A ...

  12. Lithium: Thionyl chloride battery state-of-the-art assessment...

    Office of Scientific and Technical Information (OSTI)

    Lithium: Thionyl chloride battery state-of-the-art assessment Citation Details In-Document Search Title: Lithium: Thionyl chloride battery state-of-the-art assessment You are ...

  13. Lithium-ion batteries having conformal solid electrolyte layers

    DOEpatents

    Kim, Gi-Heon; Jung, Yoon Seok

    2014-05-27

    Hybrid solid-liquid electrolyte lithium-ion battery devices are disclosed. Certain devices comprise anodes and cathodes conformally coated with an electron insulating and lithium ion conductive solid electrolyte layer.

  14. A Better Anode Design to Improve Lithium-Ion Batteries

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    A Better Anode Design to Improve Lithium-Ion Batteries ... In a lithium-ion battery, charge moves from the cathode to the ... characterization, and simulation in a novel approach to ...

  15. A Better Anode Design to Improve Lithium-Ion Batteries

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Better Anode Design to Improve Lithium-Ion Batteries ... In a lithium-ion battery, charge moves from the cathode to the ... characterization, and simulation in a novel approach to ...

  16. A Better Anode Design to Improve Lithium-Ion Batteries

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    A Better Anode Design to Improve Lithium-Ion ... In a lithium-ion battery, charge moves from the cathode to the ... characterization, and simulation in a novel approach to ...

  17. A Better Anode Design to Improve Lithium-Ion Batteries

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    A Better Anode Design to Improve Lithium-Ion Batteries Print Lithium-ion batteries are in smart phones, laptops, most other consumer electronics, and the newest electric cars. Good ...

  18. Development of Novel Electrolytes for Use in High Energy Lithium...

    Energy.gov [DOE] (indexed site)

    Development of Novel Electrolytes for Use in High Energy Lithium-Ion Batteries with Wide Operating Temperature Range Electrolytes for Use in High Energy Lithium-Ion Batteries with ...

  19. Effect of Lithium PFC Coatings on NSTX Density Control (Journal...

    Office of Scientific and Technical Information (OSTI)

    Effect of Lithium PFC Coatings on NSTX Density Control Citation Details In-Document Search Title: Effect of Lithium PFC Coatings on NSTX Density Control You are accessing a ...

  20. Solid Electrolyte: the Key for High-Voltage Lithium Batteries...

    Office of Scientific and Technical Information (OSTI)

    Solid Electrolyte: the Key for High-Voltage Lithium Batteries Citation Details In-Document Search Title: Solid Electrolyte: the Key for High-Voltage Lithium Batteries Authors: Li, ...

  1. Excellent Stability of a Lithium-Ion-Conducting Solid Electrolyte...

    Office of Scientific and Technical Information (OSTI)

    Excellent Stability of a Lithium-Ion-Conducting Solid Electrolyte upon Reversible Li+H+ Exchange in Aqueous Solutions Title: Excellent Stability of a Lithium-Ion-Conducting Solid ...

  2. San Diego County, California | Department of Energy

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    Diego County, California San Diego County, California Energy Upgrade California in San Diego County Location: San Diego County, California Seed Funding: $3.9 million-a portion of Los Angeles County's $30 million funding Target Building Types: Residential (single-family and multifamily) Website: https://sdgehomeupgrade.com Energy Upgrade California Motivates Home Improvements in San Diego County As the third largest metropolitan area in California, San Diego County plays a significant role in the

  3. Manufacturing of Protected Lithium Electrodes for Advanced Batteries |

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    Department of Energy of Protected Lithium Electrodes for Advanced Batteries Manufacturing of Protected Lithium Electrodes for Advanced Batteries PolyPlus Battery Company - Berkeley, CA A protected lithium electrode, solid electrolyte, and scaled-up manufacturing process will be developed for high-energy-density lithium batteries. This project will scale up production from a batch mode to a high-volume process. Commercial introduction of this manufacturing process could extend the driving

  4. Michael Thackeray on Lithium-air Batteries | Argonne National Laboratory

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Michael Thackeray on Lithium-air Batteries Share Description Michael Thackeray, Distinguished Fellow at Argonne National Laboratory, speaks on the new technology Lithium-air batteries, which could potentially increase energy density by 5-10 times over lithium-ion batteries. Speakers Michael Thackeray Duration 2:10 Topic Energy Energy usage Energy storage Batteries Lithium-air batteries Programs Chemical sciences & engineering Electrochemical energy storage Video ID

  5. Methods for making lithium vanadium oxide electrode materials

    DOEpatents

    Schutts, Scott M.; Kinney, Robert J.

    2000-01-01

    A method of making vanadium oxide formulations is presented. In one method of preparing lithium vanadium oxide for use as an electrode material, the method involves: admixing a particulate form of a lithium compound and a particulate form of a vanadium compound; jet milling the particulate admixture of the lithium and vanadium compounds; and heating the jet milled particulate admixture at a temperature below the melting temperature of the admixture to form lithium vanadium oxide.

  6. Expansion of Novolyte Capacity for Lithium Ion Electrolyte Production |

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    Department of Energy Novolyte Capacity for Lithium Ion Electrolyte Production Expansion of Novolyte Capacity for Lithium Ion Electrolyte Production 2012 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Program Annual Merit Review and Peer Evaluation Meeting arravt015_es_wise_2012_p.pdf (321.02 KB) More Documents & Publications Expansion of Novolyte Capacity for Lithium Ion Electrolyte Production Expansion of Novolyte Capacity for Lithium Ion Electrolyte Production FY 2011

  7. Lithium based electrochemical cell systems having a degassing agent

    DOEpatents

    Hyung, Yoo-Eup; Vissers, Donald R.; Amine, Khalil

    2012-05-01

    A lithium based electrochemical cell system includes a positive electrode; a negative electrode; an electrolyte; and a degassing agent.

  8. A Lithium Getter Pump System ---- nventors Richard Majeski, Eugene Kearns,

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    and John Schmitt | Princeton Plasma Physics Lab Lithium Getter Pump System ---- nventors Richard Majeski, Eugene Kearns, and John Schmitt This invention is a device to pump volatile gases that bond to lithium in a high vacuum environment. Typically, a crust is formed on lithium getters under the high temperatures and vacuum conditions of fusion experiments. In this invention, electromagnetic stirring of the liquid metal prevents the formation of the crust. Without stirring, the lithium must

  9. Process for the production of lithium fluoride detectors

    SciTech Connect

    Nink, R.

    1980-08-12

    A lithium fluoride detector for thermoluminescence dosimetry is produced by pulling a doped lithium fluoride monocrystal from the melt. Lithium fluoride powder with titanium added to it is used as starting material and oxygen is incorporated into the lithium fluoride crystal lattice during or after production of the crystal. If titanium dioxide is added to the starting material, the oxygen may be incorporated during production of the crystal by eliminating the oxygen from the titanium dioxide.

  10. EV Everywhere Batteries Workshop - Beyond Lithium Ion Breakout Session

    Energy Saver

    Report | Department of Energy Beyond Lithium Ion Breakout Session Report EV Everywhere Batteries Workshop - Beyond Lithium Ion Breakout Session Report Breakout session presentation for the EV Everywhere Grand Challenge: Battery Workshop on July 26, 2012 held at the Doubletree OHare, Chicago, IL. report_out-beyond_lithium_ion_b.pdf (138.93 KB) More Documents & Publications EV Everywhere Batteries Workshop - Next Generation Lithium Ion Batteries Breakout Session Report EV Everywhere

  11. EV Everywhere Batteries Workshop - Next Generation Lithium Ion...

    Energy.gov [DOE] (indexed site)

    More Documents & Publications EV Everywhere Batteries Workshop - Beyond Lithium Ion Breakout Session Report EV Everywhere Batteries Workshop - Materials Processing and ...

  12. Electrolytes - R&D for Advanced Lithium Batteries. Interfacial...

    Energy.gov [DOE] (indexed site)

    More Documents & Publications Electrolytes - R&D for Advanced Lithium Batteries. Interfacial Behavior of Electrolytes Interfacial Behavior of Electrolytes Electrolytes - ...

  13. Sparingly Solvating Electrolytes for High Energy Density Lithium-Sulfur

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Batteries - Joint Center for Energy Storage Research August 24, 2016, Videos Sparingly Solvating Electrolytes for High Energy Density Lithium-Sulfur Batteries As JCESR scientists work to develop lighter and less expensive chemistries than those used in current lithium-ion batteries, lithium-sulfur shows tremendous promise. However, current lithium-sulfur batteries require an excessive amount of electrolyte to achieve moderate cycle life. This perspective presents an alternate approach of

  14. Khalil Amine on Lithium-air Batteries | Argonne National Laboratory

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Khalil Amine on Lithium-air Batteries Share Description Khalil Amine, materials scientist at Argonne National Laboratory, speaks on the new technology Lithium-air batteries, which could potentially increase energy density by 5-10 times over lithium-ion batteries. Speakers Khalil Amine Duration 2:34 Topic Energy Energy usage Energy storage Batteries Lithium-air batteries Programs Chemical sciences & engineering Electrochemical energy storage Video ID http://youtu.be/K-rO39scjUs

  15. Sevin Rosen Funds (California) | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Sevin Rosen Funds (California) Address: 421 Kipling Street Place: Palo Alto, California Zip: 94301 Region: Bay Area Product: Venture fund Year Founded: 1981 Phone Number: (650)...

  16. California/Incentives | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    (California) Utility Grant Program Yes Alameda Municipal Power - Residential Refrigerator Efficiency Program (California) Utility Rebate Program No Alameda Municipal Power - Solar...

  17. Glendale, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Smart Grid Projects in Glendale, California City of Glendale Water and Power Smart Grid Project Registered Energy Companies in Glendale, California City of Glendale Water Power...

  18. ,"California Natural Gas Consumption by End Use"

    Energy Information Administration (EIA) (indexed site)

    Data for" ,"Data 1","California Natural Gas Consumption by End ... AM" "Back to Contents","Data 1: California Natural Gas Consumption by End Use" ...

  19. ,"California Heat Content of Natural Gas Consumed"

    Energy Information Administration (EIA) (indexed site)

    Data for" ,"Data 1","California Heat Content of Natural Gas ... 10:59:46 AM" "Back to Contents","Data 1: California Heat Content of Natural Gas Consumed

  20. California Fuel Cell Partnership | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Partnership Jump to: navigation, search Name: California Fuel Cell Partnership Address: 3300 Industrial Blvd Place: West Sacramento, California Zip: 95691 Region: Bay Area Website:...

  1. California Coastal Management Program | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Management Program Jump to: navigation, search OpenEI Reference LibraryAdd to library Legal Document- OtherOther: California Coastal Management ProgramLegal Abstract California...

  2. California Environmental Protection Agency | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Agency Jump to: navigation, search Logo: California Environmental Protection Agency Name: California Environmental Protection Agency Address: 1001 I Street, PO Box 2815 Place:...

  3. California State University CSU | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    University CSU Jump to: navigation, search Name: California State University (CSU) Place: Los Angeles, California Zip: 90802-4210 Sector: Solar Product: One of the largest higher...

  4. California State Lands Commission | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Lands Commission Jump to: navigation, search Logo: California State Lands Commission Name: California State Lands Commission Abbreviation: CSLC Address: 100 Howe Ave., Suite 100...

  5. California State Historic Preservation Officer | Open Energy...

    OpenEI (Open Energy Information) [EERE & EIA]

    Historic Preservation Officer Jump to: navigation, search Logo: California State Historic Preservation Officer Name: California State Historic Preservation Officer Address: Dept....

  6. California's 43rd congressional district: Energy Resources |...

    OpenEI (Open Energy Information) [EERE & EIA]

    can help OpenEI by expanding it. This page represents a congressional district in California. Registered Energy Companies in California's 43rd congressional district Ecosystem...

  7. California's 21st congressional district: Energy Resources |...

    OpenEI (Open Energy Information) [EERE & EIA]

    can help OpenEI by expanding it. This page represents a congressional district in California. Registered Energy Companies in California's 21st congressional district Agrimass...

  8. California Academy of Sciences | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Academy of Sciences Jump to: navigation, search Name: California Academy of Sciences Place: San Francisco, California Zip: 94103-3009 Product: Set up to explore, explain and...

  9. California's 41st congressional district: Energy Resources |...

    OpenEI (Open Energy Information) [EERE & EIA]

    can help OpenEI by expanding it. This page represents a congressional district in California. Registered Energy Companies in California's 41st congressional district BCL...

  10. California's 18th congressional district: Energy Resources |...

    OpenEI (Open Energy Information) [EERE & EIA]

    can help OpenEI by expanding it. This page represents a congressional district in California. Registered Energy Companies in California's 18th congressional district 1st Light...

  11. California Wind Systems | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Systems Jump to: navigation, search Name: California Wind Systems Address: 3411 Camino Corte Place: Carlsbad, California Zip: 92008 Region: Southern CA Area Sector: Wind energy...

  12. California Coastal Commission | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Commission Jump to: navigation, search Logo: California Coastal Commission Name: California Coastal Commission Address: 45 Fremont Street, Suite 2000 Place: San Francisco,...

  13. California's 45th congressional district: Energy Resources |...

    OpenEI (Open Energy Information) [EERE & EIA]

    can help OpenEI by expanding it. This page represents a congressional district in California. Registered Energy Companies in California's 45th congressional district Chuckawalla...

  14. California Permit Streamlining Act | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    California Permit Streamlining Act Jump to: navigation, search OpenEI Reference LibraryAdd to library Legal Document- StatuteStatute: California Permit Streamlining ActLegal...

  15. California Climate Action Registry | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Climate Action Registry Jump to: navigation, search Name: California Climate Action Registry Place: Los Angeles, California Zip: 90014 Product: Los Angeles-based NPO which develops...

  16. California Solar Energy Industries Association | Open Energy...

    OpenEI (Open Energy Information) [EERE & EIA]

    Solar Energy Industries Association Jump to: navigation, search Name: California Solar Energy Industries Association Place: Rio Vista, California Zip: 94571 Sector: Solar Product:...

  17. California National Guard Sustainability Planning, Hydrogen Fuel...

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    National Guard Sustainability Planning, Hydrogen Fuel Goals California National Guard Sustainability Planning, Hydrogen Fuel Goals Overview of California Guard Army Facilities, ANG ...

  18. Anaheim, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    congressional district.12 US Recovery Act Smart Grid Projects in Anaheim, California City of Anaheim Smart Grid Project Utility Companies in Anaheim, California City of...

  19. California's 47th congressional district: Energy Resources |...

    OpenEI (Open Energy Information) [EERE & EIA]

    US Recovery Act Smart Grid Projects in California's 47th congressional district City of Anaheim Smart Grid Project Registered Energy Companies in California's 47th...

  20. California's 40th congressional district: Energy Resources |...

    OpenEI (Open Energy Information) [EERE & EIA]

    US Recovery Act Smart Grid Projects in California's 40th congressional district City of Anaheim Smart Grid Project Registered Energy Companies in California's 40th...

  1. California's 20th congressional district: Energy Resources |...

    OpenEI (Open Energy Information) [EERE & EIA]

    California. Registered Energy Companies in California's 20th congressional district BioEnergy Solutions BES Castle Cooke Inc Great Valley Ethanol LLC Mt Poso Cogeneration Pacific...

  2. California Green Designs | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Designs Jump to: navigation, search Name: California Green Designs Place: Encino, California Zip: 91316 Sector: Buildings, Renewable Energy Product: Designs and builds...

  3. Diesel Use in California | Department of Energy

    Energy.gov [DOE] (indexed site)

    Presentation: California Energy Commission 2002deerboyd.pdf (29.99 KB) More Documents & Publications Reducing Petroleum Despendence in California: Uncertainties About ...

  4. California Energy Commissioner Carla Peterman and James

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    California Energy Commissioner Carla Peterman and James Bartridge (CEC) discuss electric ... The partnership with i-GATE has made it easier for businesses and the state of California ...

  5. Reducing Petroleum Despendence in California: Uncertainties About...

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    Petroleum Despendence in California: Uncertainties About Light-Duty Diesel Reducing Petroleum Despendence in California: Uncertainties About Light-Duty Diesel 2002 DEER Conference ...

  6. California's 27th congressional district: Energy Resources |...

    OpenEI (Open Energy Information) [EERE & EIA]

    City of Burbank Water and Power, California (Utility Company) Retrieved from "http:en.openei.orgwindex.php?titleCalifornia%27s27thcongressionaldistrict&oldid181513...

  7. California's 28th congressional district: Energy Resources |...

    OpenEI (Open Energy Information) [EERE & EIA]

    in California's 28th congressional district Angeleno Group Retrieved from "http:en.openei.orgwindex.php?titleCalifornia%27s28thcongressionaldistrict&oldid181514...

  8. California's 26th congressional district: Energy Resources |...

    OpenEI (Open Energy Information) [EERE & EIA]

    in California's 26th congressional district Angeleno Group Retrieved from "http:en.openei.orgwindex.php?titleCalifornia%27s26thcongressionaldistrict&oldid181511...

  9. California's 35th congressional district: Energy Resources |...

    OpenEI (Open Energy Information) [EERE & EIA]

    in California's 35th congressional district Angeleno Group Retrieved from "http:en.openei.orgwindex.php?titleCalifornia%27s35thcongressionaldistrict&oldid181530...

  10. California's 33rd congressional district: Energy Resources |...

    OpenEI (Open Energy Information) [EERE & EIA]

    in California's 33rd congressional district Angeleno Group Retrieved from "http:en.openei.orgwindex.php?titleCalifornia%27s33rdcongressionaldistrict&oldid181527...

  11. California's 32nd congressional district: Energy Resources |...

    OpenEI (Open Energy Information) [EERE & EIA]

    in California's 32nd congressional district Angeleno Group Retrieved from "http:en.openei.orgwindex.php?titleCalifornia%27s32ndcongressionaldistrict&oldid181525...

  12. California's 31st congressional district: Energy Resources |...

    OpenEI (Open Energy Information) [EERE & EIA]

    in California's 31st congressional district Angeleno Group Retrieved from "http:en.openei.orgwindex.php?titleCalifornia%27s31stcongressionaldistrict&oldid181523...

  13. California's 34th congressional district: Energy Resources |...

    OpenEI (Open Energy Information) [EERE & EIA]

    in California's 34th congressional district Angeleno Group Retrieved from "http:en.openei.orgwindex.php?titleCalifornia%27s34thcongressionaldistrict&oldid181528...

  14. California's 23rd congressional district: Energy Resources |...

    OpenEI (Open Energy Information) [EERE & EIA]

    23rd congressional district NGEN Partners LLC (Southern California) Retrieved from "http:en.openei.orgwindex.php?titleCalifornia%27s23rdcongressionaldistrict&oldid181505...

  15. California's 29th congressional district: Energy Resources |...

    OpenEI (Open Energy Information) [EERE & EIA]

    (Utility Company) City of Glendale, California (Utility Company) Retrieved from "http:en.openei.orgwindex.php?titleCalifornia%27s29thcongressionaldistrict&oldid181517...

  16. California's 36th congressional district: Energy Resources |...

    OpenEI (Open Energy Information) [EERE & EIA]

    in California's 36th congressional district Angeleno Group Retrieved from "http:en.openei.orgwindex.php?titleCalifornia%27s36thcongressionaldistrict&oldid181532...

  17. California Environmental Protection Agency Water Resources Control...

    OpenEI (Open Energy Information) [EERE & EIA]

    Water Resources Control Board Jump to: navigation, search Name: California Environmental Protection Agency Water Resources Control Board Place: Sacramento, California Coordinates:...

  18. California Department of Conservation | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Conservation Jump to: navigation, search Logo: California Department of Conservation Name: California Department of Conservation Abbreviation: DOC Address: 801 K Street, MS 24-01...

  19. Ramona, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    in San Diego County, California.1 Registered Energy Companies in Ramona, California Sky WindPower Corp References US Census Bureau 2005 Place to 2006 CBSA Retrieved from...

  20. California Coast Venture Forum | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    search Name: California Coast Venture Forum Address: 800 Anacapa Street, Suite A Place: Santa Barbara, California Zip: 93101 Region: Southern CA Area Year Founded: 1996 Phone...

  1. US Renewables Group (California) | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Renewables Group (California) Address: 2425 Olympic Boulevard, Suite 4050 West Place: Santa Monica, California Zip: 90404 Region: Southern CA Area Product: Private equity firm...

  2. Goshen, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    California.1 Registered Energy Companies in Goshen, California Cilion Inc Phoenix Bio Industries LLC References US Census Bureau 2005 Place to 2006 CBSA Retrieved from...

  3. University of California, Berkeley | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Berkeley Jump to: navigation, search Hydro | Hydrodynamic Testing Facilities Name University of California, Berkeley Address 1301 S 46th Street Place Richmond, California Zip 94804...

  4. Arvin, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    expanding it. Arvin is a city in Kern County, California. It falls under California's 20th congressional district.12 References US Census Bureau Incorporated place and...

  5. Huron, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    expanding it. Huron is a city in Fresno County, California. It falls under California's 20th congressional district.12 References US Census Bureau Incorporated place and...

  6. Parlier, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    it. Parlier is a city in Fresno County, California. It falls under California's 20th congressional district.12 References US Census Bureau Incorporated place and...

  7. Shafter, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    expanding it. Shafter is a city in Kern County, California. It falls under California's 20th congressional district.12 References US Census Bureau Incorporated place and...

  8. Firebaugh, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    it. Firebaugh is a city in Fresno County, California. It falls under California's 20th congressional district.12 References US Census Bureau Incorporated place and...

  9. Wasco, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    expanding it. Wasco is a city in Kern County, California. It falls under California's 20th congressional district.12 References US Census Bureau Incorporated place and...

  10. Fowler, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    it. Fowler is a city in Fresno County, California. It falls under California's 20th congressional district.12 References US Census Bureau Incorporated place and...

  11. Coalinga, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    it. Coalinga is a city in Fresno County, California. It falls under California's 20th congressional district.12 References US Census Bureau Incorporated place and...

  12. Altadena, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Altadena is a census-designated place in Los Angeles County, California.1 Registered Energy Companies in Altadena, California Direct Methanol Fuel Cell Corporation DMFCC...

  13. Blythe, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Registered Energy Companies in Blythe, California Chuckawalla Valley State Prison Energy Generation Facilities in Blythe, California Blythe Solar Power Plant References...

  14. California Water Forms | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Not provided DOI Not Provided Check for DOI availability: http:crossref.org Online Internet link for California Water Forms Citation California Water Forms(2009). Retrieved from...

  15. Secondary electron emission from lithium and lithium compounds

    DOE PAGES [OSTI]

    Capece, A. M.; Patino, M. I.; Raitses, Y.; Koel, B. E.

    2016-07-06

    In this work, measurements of electron-induced secondary electron emission ( SEE) yields of lithium as a function of composition are presented. The results are particularly relevant for magnetic fusion devices such as tokamaks, field-reversed configurations, and stellarators that consider Li as a plasma-facing material for improved plasma confinement. SEE can reduce the sheath potential at the wall and cool electrons at the plasma edge, resulting in large power losses. These effects become significant as the SEE coefficient, γe, approaches one, making it imperative to maintain a low yield surface. This work demonstrates that the yield from Li strongly depends onmore » chemical composition and substantially increases after exposure to oxygen and water vapor. The total yield was measured using a retarding field analyzer in ultrahigh vacuum for primary electron energies of 20-600 eV. The effect of Li composition was determined by introducing controlled amounts of O2 and H2O vapor while monitoring film composition with Auger electron spectroscopy and temperature programmed desorption. The results show that the energy at which γe = 1 decreases with oxygen content and is 145 eV for a Li film that is 17% oxidized and drops to less than 25 eV for a fully oxidized film. This work has important implications for laboratory plasmas operating under realistic vacuum conditions in which oxidation significantly alters the electron emission properties of Li walls. Published by AIP Publishing.« less

  16. RECOVERY AND SEPARATION OF LITHIUM VALUES FROM SALVAGE SOLUTIONS

    DOEpatents

    Hansford, D.L.; Raabe, E.W.

    1963-08-20

    Lithium values can be recovered from an aqueous basic solution by reacting the values with a phosphate salt soluble in the solution, forming an aqueous slurry of the resultant aqueous insoluble lithium phosphate, contacting the slurry with an organic cation exchange resin in the acid form until the slurry has been clarified, and thereafter recovering lithium values from the resin. (AEC)

  17. Lithium-Ion Battery Recycling Facilities | Department of Energy

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    Lithium-Ion Battery Recycling Facilities Lithium-Ion Battery Recycling Facilities 2012 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Program Annual Merit Review and Peer Evaluation Meeting arravt020_es_coy_2012_p.pdf (1.72 MB) More Documents & Publications Lithium-Ion Battery Recycling Facilities Recycling Hybrid and Elecectric Vehicle Batteries EA-1722: Final Environmental Assessment

  18. UNIVERSITY OF CALIFORNIA

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Jean-Luc Vay With inputs from J. Amundson, J. Cary, W. Mori, C.-K. Ng, R. Ryne, J. Qiang Exascale Requirements Reviews: High Energy Physics June 10-12, 2015 Traditional HPC needs: particle accelerators 2 2 UNIVERSITY OF CALIFORNIA Office of Science Advanced s imula.ons p lay a n i ncreasingly i mportant r ole in the design, o pera.on and t uning o f a ccelerators. CERN ( HL---)LHC FNAL P IP(---II/III) "Conven.onal a ccelerators" accelerate b eams i n R F c avi.es "Advanced c

  19. Reciprocal Lithium-ion Cell with Novel Lithium-Free Cathode and Pre-Lithiated Carbonaceus Anode

    SciTech Connect

    Ravdel, Boris

    2010-05-19

    Phase I of this program was focused mostly on the testing of pre-lithiated carbonaceous negative-electrode material as the source of the active lithium in lithium-ion cells coupled with "lithium-free" positive-electrode material. The secondary objective was na attempt to determine the ways of developing such as inexpense, stable, and environmentally benign "lithium-free" high-energy cathode material.

  20. A Stable Fluorinated and Alkylated Lithium Malonatoborate Salt for Lithium Ion Battery Application

    DOE PAGES [OSTI]

    Dai, Sheng; Sun, Xiao-Guang

    2015-01-01

    A new fluorinated and alkylated lithium malonatoborate salt, lithium bis(2-methyl-2-fluoromalonato)borate (LiBMFMB), has been synthesized for lithium ion battery application. A 0.8 M LiBMFMB solution is obtained in a mixture of ethylene carbonate (EC) and ethyl methyl carbonate (EMC) (1:2 by wt.). The new LiBMFMB based electrolyte exhibits good cycling stability and rate capability in LiNi0.5Mn1.5O4 and graphite based half-cells.

  1. A Stable Fluorinated and Alkylated Lithium Malonatoborate Salt for Lithium Ion Battery Application

    SciTech Connect

    Wan, Shun; Jiang, Xueguang; Guo, Bingkun; Dai, Sheng; Goodenough, John B.; Sun, Xiao-Guang

    2015-04-27

    A new fluorinated and alkylated lithium malonatoborate salt, lithium bis(2-methyl-2-fluoromalonato)borate (LiBMFMB), has been synthesized for lithium ion battery application. A 0.8 M LiBMFMB solution is obtained in a mixture of ethylene carbonate (EC) and ethyl methyl carbonate (EMC) (1:2 by wt.). The new LiBMFMB based electrolyte exhibits good cycling stability and rate capability in LiNi0.5Mn1.5O4 and graphite based half-cells.

  2. Enhanced lithium ion storage in nanoimprinted carbon

    SciTech Connect

    Wang, Peiqi; Chen, Qian Nataly; Li, Jiangyu; Xie, Shuhong; Liu, Xiaoyan

    2015-07-27

    Disordered carbons processed from polymers have much higher theoretical capacity as lithium ion battery anode than graphite, but they suffer from large irreversible capacity loss and have poor cyclic performance. Here, a simple process to obtain patterned carbon structure from polyvinylpyrrolidone was demonstrated, combining nanoimprint lithography for patterning and three-step heat treatment process for carbonization. The patterned carbon, without any additional binders or conductive fillers, shows remarkably improved cycling performance as Li-ion battery anode, twice as high as the theoretical value of graphite at 98 cycles. Localized electrochemical strain microscopy reveals the enhanced lithium ion activity at the nanoscale, and the control experiments suggest that the enhancement largely originates from the patterned structure, which improves surface reaction while it helps relieving the internal stress during lithium insertion and extraction. This study provides insight on fabricating patterned carbon architecture by rational design for enhanced electrochemical performance.

  3. Electrochemical Lithium Ion Battery Performance Model

    Energy Science and Technology Software Center

    2007-03-29

    The Electrochemical Lithium Ion Battery Performance Model allows for the computer prediction of the basic thermal, electrical, and electrochemical performance of a lithium ion cell with simplified geometry. The model solves governing equations describing the movement of lithium ions within and between the negative and positive electrodes. The governing equations were first formulated by Fuller, Doyle, and Newman and published in J. Electrochemical Society in 1994. The present model solves the partial differential equations governingmore » charge transfer kinetics and charge, species, heat transports in a computationally-efficient manner using the finite volume method, with special consideration given for solving the model under conditions of applied current, voltage, power, and load resistance.« less

  4. Lithium-aluminum-magnesium electrode composition

    DOEpatents

    Melendres, Carlos A.; Siegel, Stanley

    1978-01-01

    A negative electrode composition is presented for use in a secondary, high-temperature electrochemical cell. The cell also includes a molten salt electrolyte of alkali metal halides or alkaline earth metal halides and a positive electrode including a chalcogen or a metal chalcogenide as the active electrode material. The negative electrode composition includes up to 50 atom percent lithium as the active electrode constituent and a magnesium-aluminum alloy as a structural matrix. Various binary and ternary intermetallic phases of lithium, magnesium, and aluminum are formed but the electrode composition in both its charged and discharged state remains substantially free of the alpha lithium-aluminum phase and exhibits good structural integrity.

  5. Sulfur-Graphene Oxide Nanocomposite Cathodes for Lithium/Sulfur Cells -

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Energy Innovation Portal Vehicles and Fuels Vehicles and Fuels Energy Storage Energy Storage Advanced Materials Advanced Materials Find More Like This Return to Search Sulfur-Graphene Oxide Nanocomposite Cathodes for Lithium/Sulfur Cells Lawrence Berkeley National Laboratory Contact LBL About This Technology Publications: PDF Document Publication LBNL Commercial Analysis Report (1,062 KB) Technology Marketing Summary A Berkeley Lab team headed by Yuegang Zhang and Elton Cairns has developed

  6. A Two-Dimensional Thermal-Electrochemical Model for Prismatic Lithium Ion

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Cells - Energy Innovation Portal Energy Storage Energy Storage Find More Like This Return to Search A Two-Dimensional Thermal-Electrochemical Model for Prismatic Lithium Ion Cells National Renewable Energy Laboratory Contact NREL About This Technology Technology Marketing Summary Existing battery management algorithms rely upon empirical correlations between the cell voltage and the load profile. This approach limits the predictive ability of the battery management system to forecast

  7. Internal Short Circuit Device for Improved Lithium-Ion Battery Design -

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Energy Innovation Portal Vehicles and Fuels Vehicles and Fuels Energy Storage Energy Storage Find More Like This Return to Search Internal Short Circuit Device for Improved Lithium-Ion Battery Design National Renewable Energy Laboratory Contact NREL About This Technology Publications: PDF Document Publication NREL Internal Short Circuit (ISC) Fact Sheet (321 KB) Technology Marketing Summary Energy storage cells (also referred to herein as "cells" or "batteries") sold for

  8. Lithium metal reduction of plutonium oxide to produce plutonium metal

    DOEpatents

    Coops, Melvin S.

    1992-01-01

    A method is described for the chemical reduction of plutonium oxides to plutonium metal by the use of pure lithium metal. Lithium metal is used to reduce plutonium oxide to alpha plutonium metal (alpha-Pu). The lithium oxide by-product is reclaimed by sublimation and converted to the chloride salt, and after electrolysis, is removed as lithium metal. Zinc may be used as a solvent metal to improve thermodynamics of the reduction reaction at lower temperatures. Lithium metal reduction enables plutonium oxide reduction without the production of huge quantities of CaO--CaCl.sub.2 residues normally produced in conventional direct oxide reduction processes.

  9. Polymeric electrolytes for ambient temperature lithium batteries

    SciTech Connect

    Farrington, G.C. . Dept. of Materials Science and Engineering)

    1991-07-01

    A new type of highly conductive Li{sup +} polymer electrolyte, referred to as the Innovision polymer electrolyte, is completely amorphous at room temperature and has an ionic conductivity in the range of 10{sup {minus}3} S/cm. This report discusses the electrochemical characteristics (lithium oxidation and reduction), conductivity, and physical properties of Innovision electrolytes containing various dissolved salts. These electrolytes are particularly interesting since they appear to have some of the highest room-temperature lithium ion conductivities yet observed among polymer electrolytes. 13 refs. 11 figs., 2 tabs.

  10. Electrolytic orthoborate salts for lithium batteries

    DOEpatents

    Angell, Charles Austen; Xu, Wu

    2008-01-01

    Orthoborate salts suitable for use as electrolytes in lithium batteries and methods for making the electrolyte salts are provided. The electrolytic salts have one of the formulae (I). In this formula anionic orthoborate groups are capped with two bidentate chelating groups, Y1 and Y2. Certain preferred chelating groups are dibasic acid residues, most preferably oxalyl, malonyl and succinyl, disulfonic acid residues, sulfoacetic acid residues and halo-substituted alkylenes. The salts are soluble in non-aqueous solvents and polymeric gels and are useful components of lithium batteries in electrochemical devices.

  11. Electrolytic orthoborate salts for lithium batteries

    DOEpatents

    Angell, Charles Austen [Mesa, AZ; Xu, Wu [Tempe, AZ

    2009-05-05

    Orthoborate salts suitable for use as electrolytes in lithium batteries and methods for making the electrolyte salts are provided. The electrolytic salts have one of the formulae (I). In this formula anionic orthoborate groups are capped with two bidentate chelating groups, Y1 and Y2. Certain preferred chelating groups are dibasic acid residues, most preferably oxalyl, malonyl and succinyl, disulfonic acid residues, sulfoacetic acid residues and halo-substituted alkylenes. The salts are soluble in non-aqueous solvents and polymeric gels and are useful components of lithium batteries in electrochemical devices.

  12. Solid composite electrolytes for lithium batteries

    DOEpatents

    Kumar, Binod; Scanlon, Jr., Lawrence G.

    2001-01-01

    Solid composite electrolytes are provided for use in lithium batteries which exhibit moderate to high ionic conductivity at ambient temperatures and low activation energies. In one embodiment, a polymer-ceramic composite electrolyte containing poly(ethylene oxide), lithium tetrafluoroborate and titanium dioxide is provided in the form of an annealed film having a room temperature conductivity of from 10.sup.-5 S cm.sup.-1 to 10.sup.-3 S cm.sup.-1 and an activation energy of about 0.5 eV.

  13. Retrofit California Overview and Final Reports

    SciTech Connect

    Choy, Howard; Rosales, Ana

    2014-03-01

    Energy efficiency retrofits (also called upgrades) are widely recognized as a critical component to achieving energy savings in the building sector to help lower greenhouse gas (GHG) emissions. To date, however, upgrades have accounted for only a small percentage of aggregate energy savings in building stock, both in California and nationally. Although the measures and technologies to retrofit a building to become energy efficient are readily deployed, establishing this model as a standard practice remains elusive. Retrofit California sought to develop and test new program models to increase participation in the energy upgrade market in California. The Program encompassed 24 pilot projects, conducted between 2010 and mid-2013 and funded through a $30 million American Recovery and Reinvestment Act (ARRA) grant from the U.S. Department of Energy’s (DOE) Better Buildings Neighborhood Program (BBNP). The broad scope of the Program can be seen in the involvement of the following regionally based Grant Partners: Los Angeles County (as prime grantee); Association of Bay Area Governments (ABAG), consisting of: o StopWaste.org for Alameda County o Regional Climate Protection Authority (RCPA) for Sonoma County o SF Environment for the City and County of San Francisco o City of San Jose; California Center for Sustainable Energy (CCSE) for the San Diego region; Sacramento Municipal Utilities District (SMUD). Within these jurisdictions, nine different types of pilots were tested with the common goal of identifying, informing, and educating the people most likely to undertake energy upgrades (both homeowners and contractors), and to provide them with incentives and resources to facilitate the process. Despite its limited duration, Retrofit California undoubtedly succeeded in increasing awareness and education among home and property owners, as well as contractors, realtors, and community leaders. However, program results indicate that a longer timeframe will be needed to

  14. Lithium Surface Coatings for Improved Plasma Performance in NSTX

    SciTech Connect

    Kugel, H W; Ahn, J -W; Allain, J P; Bell, R; Boedo, J; Bush, C; Gates, D; Gray, T; Kaye, S; Kaita, R; LeBlanc, B; Maingi, R; Majeski, R; Mansfield, D; Menard, J; Mueller, D; Ono, M; Paul, S; Raman, R; Roquemore, A L; Ross, P W; Sabbagh, S; Schneider, H; Skinner, C H; Soukhanovskii, V; Stevenson, T; Timberlake, J; Wampler, W R

    2008-02-19

    NSTX high-power divertor plasma experiments have shown, for the first time, significant and frequent benefits from lithium coatings applied to plasma facing components. Lithium pellet injection on NSTX introduced lithium pellets with masses 1 to 5 mg via He discharges. Lithium coatings have also been applied with an oven that directed a collimated stream of lithium vapor toward the graphite tiles of the lower center stack and divertor. Lithium depositions from a few mg to 1 g have been applied between discharges. Benefits from the lithium coating were sometimes, but not always seen. These improvements sometimes included decreases plasma density, inductive flux consumption, and ELM frequency, and increases in electron temperature, ion temperature, energy confinement and periods of MHD quiescence. In addition, reductions in lower divertor D, C, and O luminosity were measured.

  15. Santa Barbara County, California Data Dashboard

    Energy.gov [DOE]

    The data dashboard for Santa Barbara County, California, a partner in the Better Buildings Neighborhood Program.

  16. Lithium pellet production (LiPP): A device for the production of small spheres of lithium

    SciTech Connect

    Fiflis, P.; Andrucyzk, D.; McGuire, M.; Curreli, D.; Ruzic, D. N.; Roquemore, A. L.

    2013-06-15

    With lithium as a fusion material gaining popularity, a method for producing lithium pellets relatively quickly has been developed for NSTX. The Lithium Pellet Production device is based on an injector with a sub-millimeter diameter orifice and relies on a jet of liquid lithium breaking apart into small spheres via the Plateau-Rayleigh instability. A prototype device is presented in this paper and for a pressure difference of {Delta}P= 5 Torr, spheres with diameters between 0.91 < D < 1.37 mm have been produced with an average diameter of D= 1.14 mm, which agrees with the developed theory. Successive tests performed at Princeton Plasma Physics Laboratory with Wood's metal have confirmed the dependence of sphere diameter on pressure difference as predicted.

  17. Multi-layered, chemically bonded lithium-ion and lithium/air...

    Office of Scientific and Technical Information (OSTI)

    Disclosed are multilayer, porous, thin-layered lithium-ion batteries that include an inorganic separator as a thin layer that is chemically bonded to surfaces of positive and ...

  18. Lithium Polysulfidophosphates: A Family of Lithium-Conducting Sulfur-Rich Compounds for Lithium-Sulfur Batteries

    SciTech Connect

    Lin, Zhan; Liu, Zengcai; Fu, Wujun; Dudney, Nancy J; Liang, Chengdu

    2013-01-01

    Given the great potential for improving the energy density of state-of-the-art lithium-ion batteries by a factor of 5, a breakthrough in lithium-sulfur (Li-S) batteries will have a dramatic impact in a broad scope of energy related fields. Conventional Li-S batteries that use liquid electrolytes are intrinsically short-lived with low energy efficiency. The challenges stem from the poor electronic and ionic conductivities of elemental sulfur and its discharge products. We report herein lithium polysulfidophosphates (LPSP), a family of sulfur-rich compounds, as the enabler of long-lasting and energy-efficient Li-S batteries. LPSP have ionic conductivities of 3.0 10-5 S cm-1 at 25 oC, which is 8 orders of magnitude higher than that of Li2S (~10-13 S cm-1). The high Li-ion conductivity of LPSP is the salient characteristic of these compounds that impart the excellent cycling performance to Li-S batteries. In addition, the batteries are configured in an all-solid state that promises the safe cycling of high-energy batteries with metallic lithium anodes.

  19. Pulsed deuterium lithium nuclear reactor

    SciTech Connect

    Fischer, A.G.

    1980-01-08

    A nuclear reactor that burns hydrogen bomb material 6-lithium deuterotritide to helium in successive microexplosions which are ignited electrically and enclosed by this same molten material, and that permits the conversion of the reaction heat into useful electrical power. A specially-constructed high-current pulse machine is discharged via a thermally-preformed highly conducting path through a mass of the molten salt 6lid1-xtx (0

  20. California Enterprise Development Authority- Statewide PACE Program (California)

    Energy.gov [DOE]

    FIGTREE Energy Financing is administering a Property Assessed Clean Energy (PACE) financing program in a number of California cities and counties through a partnership with the Pacific Housing &...

  1. Parabolic lithium mirror for a laser-driven hot plasma producing device

    DOEpatents

    Baird, James K.

    1979-06-19

    A hot plasma producing device is provided, wherein pellets, singly injected, of frozen fuel are each ignited with a plurality of pulsed laser beams. Ignition takes place within a void area in liquid lithium contained within a pressure vessel. The void in the liquid lithium is created by rotating the pressure vessel such that the free liquid surface of molten lithium therein forms a paraboloid of revolution. The paraboloid functions as a laser mirror with a reflectivity greater than 90%. A hot plasma is produced when each of the frozen deuterium-tritium pellets sequentially arrive at the paraboloid focus, at which time each pellet is illuminated by the plurality of pulsed lasers whose rays pass through circular annuli across the top of the paraboloid. The beams from the lasers are respectively directed by associated mirrors, or by means of a single conical mirror in another embodiment, and by the mirror-like paraboloid formed by the rotating liquid lithium onto the fuel pellet such that the optical flux reaching the pellet can be made to be uniform over 96% of the pellet surface area. The very hot plasma produced by the action of the lasers on the respective singly injected fuel pellets in turn produces a copious quantity of neutrons and X-rays such that the device has utility as a neutron source or as an x-ray source. In addition, the neutrons produced in the device may be utilized to produce tritium in a lithium blanket and is thus a mechanism for producing tritium.

  2. Los Angeles County, California | Department of Energy

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    County, California Los Angeles County, California Los Angeles County, California In order to make opportunities for home energy upgrades clear and consistent for the 10 million people living in Los Angeles County, the Los Angeles County Office of Sustainability decided to promote a single, regional residential efficiency program. The State of California had previously developed the statewide Energy Upgrade California program, which Los Angeles and other counties agreed to support through grant

  3. Burris Park, California, Site Fact Sheet

    Office of Legacy Management (LM)

    Burris Park, California, Site. This site is managed by the U.S. Department of Energy Office of Legacy Management as an Other Site under the Formerly Utilized Sites Remedial Action Program. Burris Park, California, Site Location of the Burris Park, California, Site Site Description and History The Burris Park, California, Site, formerly the Burris Park Field Station, is located at 6500 Clinton Avenue, Kingsburg, California. Kingsburg is a rural agricultural community in the San Joaquin Valley,

  4. Sonoma County, California | Department of Energy

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    Sonoma County, California Sonoma County, California Windsor Efficiency PAYS® Location: Town of Windsor in Sonoma County, California Seed Funding: $665,000-a portion of Los Angeles County's $30 million funding Target Building Types: Residential (single-family, multifamily) Website: energyupgradeca.org/county/sonoma/windsor_efficiency Learn more: Read program design details Read program news Promoting Energy Efficiency in Windsor, California, With Water Efficiency Efforts California is known for

  5. Sandia National Laboratories: Locations: Livermore, California: Visiting

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Sandia/California California Livermore, California administration building Our location and hours of operation Sandia/California is located at 7011 East Avenue in Livermore, Calif., a suburban community about 45 miles east of San Francisco. Positioned at the eastern edge of the San Francisco Bay Area, Sandia is within easy commuting distance of many affordable housing communities in San Joaquin County and the Central Valley. The official hours of operation at Sandia/California are from 7:30

  6. California Natural Gas Gross Withdrawals and Production

    Energy Information Administration (EIA) (indexed site)

    U.S. Offshore U.S. State Offshore Federal Offshore U.S. Alaska Alaska Onshore Alaska Offshore Alaska State Offshore Arkansas California California Onshore California Offshore California State Offshore Federal Offshore California Colorado Federal Offshore Gulf of Mexico Federal Offshore Alabama Federal Offshore Louisiana Federal Offshore Texas Kansas Louisiana Louisiana Onshore Louisiana Offshore Louisiana State Offshore Montana New Mexico North Dakota Ohio Oklahoma Pennsylvania Texas Texas

  7. Ionic liquids for rechargeable lithium batteries

    SciTech Connect

    Salminen, Justin; Papaiconomou, Nicolas; Kerr, John; Prausnitz,John; Newman, John

    2005-09-29

    We have investigated possible anticipated advantages of ionic-liquid electrolytes for use in lithium-ion batteries. Thermal stabilities and phase behavior were studied by thermal gravimetric analysis and differential scanning calorimetry. The ionic liquids studied include various imidazoliumTFSI systems, pyrrolidiniumTFSI, BMIMPF{sub 6}, BMIMBF{sub 4}, and BMIMTf. Thermal stabilities were measured for neat ionic liquids and for BMIMBF{sub 4}-LiBF{sub 4}, BMIMTf-LiTf, BMIMTFSI-LiTFSI mixtures. Conductivities have been measured for various ionic-liquid lithium-salt systems. We show the development of interfacial impedance in a Li|BMIMBF{sub 4} + LiBF{sub 4}|Li cell and we report results from cycling experiments for a Li|BMIMBF{sub 4} + 1 mol/kg LIBF{sub 4}|C cell. The interfacial resistance increases with time and the ionic liquid reacts with the lithium electrode. As expected, imidazolium-based ionic liquids react with lithium electrodes. We seek new ionic liquids that have better chemical stabilities.

  8. Electrothermal Analysis of Lithium Ion Batteries

    SciTech Connect

    Pesaran, A.; Vlahinos, A.; Bharathan, D.; Duong, T.

    2006-03-01

    This report presents the electrothermal analysis and testing of lithium ion battery performance. The objectives of this report are to: (1) develop an electrothermal process/model for predicting thermal performance of real battery cells and modules; and (2) use the electrothermal model to evaluate various designs to improve battery thermal performance.

  9. Rechargeable thin-film lithium batteries

    SciTech Connect

    Bates, J.B.; Gruzalski, G.R.; Dudney, N.J.; Luck, C.F.; Yu, X.

    1993-09-01

    Rechargeable thin-film batteries consisting of lithium metal anodes, an amorphous inorganic electrolyte, and cathodes of lithium intercalation compounds have been fabricated and characterized. These include Li-TiS{sub 2}, Li-V{sub 2}O{sub 5}, and Li-Li{sub x}Mn{sub 2}O{sub 4} cells with open circuit voltages at full charge of about 2.5 V, 3.7 V, and 4.2 V, respectively. The realization of these robust cells, which can be cycled thousands of times, was possible because of the stability of the amorphous lithium electrolyte, lithium phosphorus oxynitride. This material has a typical composition of Li{sub 2.9}PO{sub 3.3}N{sub 0.46}and a conductivity at 25 C of 2 {mu}S/cm. The thin-film cells have been cycled at 100% depth of discharge using current densities of 5 to 100 {mu}A/cm{sup 2}. Over most of the charge-discharge range, the internal resistance appears to be dominated by the cathode, and the major source of the resistance is the diffusion of Li{sup +} ions from the electrolyte into the cathode. Chemical diffusion coefficients were determined from ac impedance measurements.

  10. Thin-film Rechargeable Lithium Batteries

    DOE R&D Accomplishments

    Bates, J. B.; Gruzalski, G. R.; Dudney, N. J.; Luck, C. F.; Yu, X.

    1993-11-01

    Rechargeable thin films batteries with lithium metal anodes, an amorphous inorganic electrolyte, and cathodes of lithium intercalation compounds have been fabricated and characterized. The cathodes include TiS{sub 2}, the {omega} phase of V{sub 2}O{sub 5}, and the cubic spinel Li{sub x}Mn{sub 2}O{sub 4} with open circuit voltages at full charge of about 2.5 V, 3.7 V, and 4.2 V, respectively. The development of these robust cells, which can be cycled thousands of times, was possible because of the stability of the amorphous lithium electrolyte, lithium phosphorus oxynitride. This material has a typical composition of Li{sub 2.9}PO{sub 3.3}N{sub 0.46} and a conductivity at 25 C of 2 {mu}S/cm. Thin film cells have been cycled at 100% depth of discharge using current densities of 2 to 100 {mu}A/cm{sup 2}. The polarization resistance of the cells is due to the slow insertion rate of Li{sup +} ions into the cathode. Chemical diffusion coefficients for Li{sup +} ions in the three types of cathodes have been estimated from the analysis of ac impedance measurements.

  11. Solar Parking Structure in California

    Office of Energy Efficiency and Renewable Energy (EERE)

    This photograph features the photovoltaic (PV) system at the Cal Expo in Sacramento, California, that was "made for the shade," but it does much more. Installed in September 2000, the 540-kilowatt...

  12. SCE- California Advanced Homes Incentives

    Energy.gov [DOE]

    Southern California Edison offers an incentive for home builders to build homes which exceed 2008 Title 24 standards by 15%. The program is open to all single-family and multi-family new...

  13. Chula Vista, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    California. It falls under California's 51st congressional district.12 Registered Energy Companies in Chula Vista, California Green Star Products Inc GSPI References US...

  14. University of Southern California-Energy Institute | Open Energy...

    OpenEI (Open Energy Information) [EERE & EIA]

    California-Energy Institute Jump to: navigation, search Name: University of Southern California-Energy Institute Place: Los Angeles, California Zip: 90089 Region: Southern CA Area...

  15. Colusa County, California: Energy Resources | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Generation Facilities in Colusa County, California Wadham Energy LP Biomass Facility Williams Biomass Facility Places in Colusa County, California Arbuckle, California Colusa,...

  16. The California Biodiesel Alliance CBA | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Biodiesel Alliance CBA Jump to: navigation, search Name: The California Biodiesel Alliance (CBA) Place: California Product: California-based non-profit corporation promoting...

  17. California Center for Sustainable Energy CCSE | Open Energy Informatio...

    OpenEI (Open Energy Information) [EERE & EIA]

    San Diego, California Zip: 92123 Product: California-based technical assistance and education centre for energy awareness. References: California Center for Sustainable Energy...

  18. Southern California Edison Company SCE | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Southern California Edison Company SCE Jump to: navigation, search Name: Southern California Edison Company (SCE) Place: Rosemead, California Zip: 91770 Sector: Renewable Energy...

  19. California Division of Water Rights | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    Division of Water Rights Jump to: navigation, search Logo: California Division of Water Rights Name: California Division of Water Rights Place: Sacramento, California Phone Number:...

  20. RockPort Capital Partners (California) | Open Energy Information

    OpenEI (Open Energy Information) [EERE & EIA]

    RockPort Capital Partners (California) Jump to: navigation, search Logo: RockPort Capital Partners (California) Name: RockPort Capital Partners (California) Address: 3000 Sand Hill...

  1. California Homebuyers Find More Value in Energy-Efficient Labeled...

    Energy.gov [DOE] (indexed site)

    Energy Upgrade California in Los Angeles County, a Better Buildings Neighborhood Program ... Researchers at the University of California, Berkeley, and the University of California, ...

  2. Network Member Helps City Climb CoolCalifornia Challenge Leaderboard...

    Energy Saver

    The City of Claremont, California, climbed the CoolCalifornia Challenge leaderboard ... California residents participating in the challenge record their energy use, water ...

  3. Transportation and Stationary Power Integration Workshop: A California...

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    A California Perspective Transportation and Stationary Power Integration Workshop: A California Perspective Overview of California regulations, latest funded hydrogen stations, and ...

  4. California Construction Storm Water Program Website | Open Energy...

    OpenEI (Open Energy Information) [EERE & EIA]

    California's Construction Storm Water Program. Author California State Water Resources Control Board Published California State Water Resources Control Board, Date Not Provided DOI...

  5. Desert Hot Springs, California: Energy Resources | Open Energy...

    OpenEI (Open Energy Information) [EERE & EIA]

    Riverside County, California. It falls under California's 41st congressional district.12 Registered Energy Companies in Desert Hot Springs, California BCL Associates Inc...

  6. Implications of NSTX Lithium Results for Magnetic Fusion Research

    SciTech Connect

    M. Ono, M.G. Bell, R.E. Bell, R. Kaita, H.W. Kugel, B.P. LeBlanc, J.M. Canik, S. Diem, S.P.. Gerhardt, J. Hosea, S. Kaye, D. Mansfield, R. Maingi, J. Menard, S. F. Paul, R. Raman, S.A. Sabbagh, C.H. Skinner, V. Soukhanovskii, G. Taylor, and the NSTX Research Team

    2010-01-14

    Lithium wall coating techniques have been experimentally explored on NSTX for the last five years. The lithium experimentation on NSTX started with a few milligrams of lithium injected into the plasma as pellets and it has evolved to a lithium evaporation system which can evaporate up to ~ 100 g of lithium onto the lower divertor plates between lithium reloadings. The unique feature of the lithium research program on NSTX is that it can investigate the effects of lithium in H-mode divertor plasmas. This lithium evaporation system thus far has produced many intriguing and potentially important results; the latest of these are summarized in a companion paper by H. Kugel. In this paper, we suggest possible implications and applications of the NSTX lithium results on the magnetic fusion research which include electron and global energy confinement improvements, MHD stability enhancement at high beta, ELM control, H-mode power threshold reduction, improvements in radio frequency heating and non-inductive plasma start-up performance, innovative divertor solutions and improved operational efficiency.

  7. Better Lithium-Ion Batteries Are On The Way From Berkeley Lab

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Lithium-Ion Batteries A Better Lithium-ion Battery on the Way Simulations Reveal How New Polymer Absorbs Eight Times the Lithium of Current Designs September 23, 2011 Paul Preuss,...

  8. Solid state thin film battery having a high temperature lithium alloy anode

    DOEpatents

    Hobson, David O.

    1998-01-01

    An improved rechargeable thin-film lithium battery involves the provision of a higher melting temperature lithium anode. Lithium is alloyed with a suitable solute element to elevate the melting point of the anode to withstand moderately elevated temperatures.

  9. Beyond Lithium-Ion Batteries - Joint Center for Energy Storage Research

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    7, 2014, Videos Beyond Lithium-Ion Batteries beyond_lithium_ion_batteris_audio JCESR Director George Crabtree and Deputy Director Jeff Chamberlain discuss how JCESR will go beyond lithium ion batteries in this audio podcast

  10. Biomass Energy Production in California 2002: Update of the California Biomass Database

    SciTech Connect

    Morris, G.

    2002-12-01

    An updated version of the California Biomass Energy Database, which summarizes California's biomass energy industry using data from 2000 and 2001.

  11. Unraveling the Voltage-Fade Mechanism in High-Energy-Density Lithium-Ion Batteries: Origin of the Tetrahedral Cations for Spinel Conversion

    SciTech Connect

    Mohanty, Debasish; Li, Jianlin; Abraham, Daniel P.; Huq, Ashfia; Payzant, E. Andrew; Wood, David L.; Daniel, Claus

    2014-09-30

    Discovery of high-voltage layered lithium-and manganese-rich (LMR) composite oxide electrode has dramatically enhanced the energy density of current Li-ion energy storage systems. However, practical usage of these materials is currently not viable because of their inability to maintain a consistent voltage profile (voltage fading) during subsequent charge-discharge cycles. This report rationalizes the cause of this voltage fade by providing the evidence of layer to spinel-like (LSL) structural evolution pathways in the host Li1.2Mn0.55Ni0.15Co0.1O2 LMR composite oxide. By employing neutron powder diffraction, and temperature dependent magnetic susceptibility, we show that LSL structural rearrangement in LMR oxide occurs through a tetrahedral cation intermediate via: i) diffusion of lithium atoms from octahedral to tetrahedral sites of the lithium layer [(LiLioct →LiLitet] which is followed by the dispersal of the lithium ions from the adjacent octahedral site of the metal layer to the tetrahedral sites of lithium layer [LiTM oct → LiLitet]; and ii) migration of Mn from the octahedral sites of the transition metal layer to the permanent octahedral site of lithium layer via tetrahedral site of lithium layer [MnTMoct MnLitet MnLioct)]. The findings opens the door to the potential routes to mitigate this atomic restructuring in the high-voltage LMR composite oxide cathodes by manipulating the composition/structure for practical use in high-energy-density lithium-ion batteries.

  12. Unraveling the Voltage-Fade Mechanism in High-Energy-Density Lithium-Ion Batteries: Origin of the Tetrahedral Cations for Spinel Conversion

    DOE PAGES [OSTI]

    Mohanty, Debasish; Li, Jianlin; Abraham, Daniel P.; Huq, Ashfia; Payzant, E. Andrew; Wood, David L.; Daniel, Claus

    2014-09-30

    Discovery of high-voltage layered lithium-and manganese-rich (LMR) composite oxide electrode has dramatically enhanced the energy density of current Li-ion energy storage systems. However, practical usage of these materials is currently not viable because of their inability to maintain a consistent voltage profile (voltage fading) during subsequent charge-discharge cycles. This report rationalizes the cause of this voltage fade by providing the evidence of layer to spinel-like (LSL) structural evolution pathways in the host Li1.2Mn0.55Ni0.15Co0.1O2 LMR composite oxide. By employing neutron powder diffraction, and temperature dependent magnetic susceptibility, we show that LSL structural rearrangement in LMR oxide occurs through a tetrahedral cationmore » intermediate via: i) diffusion of lithium atoms from octahedral to tetrahedral sites of the lithium layer [(LiLioct →LiLitet] which is followed by the dispersal of the lithium ions from the adjacent octahedral site of the metal layer to the tetrahedral sites of lithium layer [LiTM oct → LiLitet]; and ii) migration of Mn from the octahedral sites of the transition metal layer to the permanent octahedral site of lithium layer via tetrahedral site of lithium layer [MnTMoct MnLitet MnLioct)]. The findings opens the door to the potential routes to mitigate this atomic restructuring in the high-voltage LMR composite oxide cathodes by manipulating the composition/structure for practical use in high-energy-density lithium-ion batteries.« less

  13. Modeling the Performance and Cost of Lithium-Ion Batteries for...

    Office of Scientific and Technical Information (OSTI)

    National Laboratory for lithium-ion battery packs used in automotive transportation. ... calculated by accounting for every step in the lithium-ionbattery manufacturing process. ...

  14. Automotive Lithium-ion Battery Supply Chain and U.S. Competitiveness...

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    Automotive Lithium-ion Battery Supply Chain and U.S. Competitiveness Considerations Automotive Lithium-ion Battery Supply Chain and U.S. Competitiveness Considerations This Clean ...

  15. Model for the Fabrication of Tailored Materials for Lithium-Ion...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Model for the Fabrication of Tailored Materials for Lithium-Ion Batteries Technology available for licensing: Safe, stable and high-capacity cathodes for lithium-ion batteries ...

  16. High Conductivity Single-ion Cross-linked Polymers for Lithium...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    High Conductivity Single-ion Cross-linked Polymers for Lithium Batteries and Fuel Cells ... for use as membranes in lithium batteries, fuel cells, and electrochromic windows. ...

  17. Carbon/Sulfur Nanocomposites and Additives for High-Energy Lithium...

    Energy.gov [DOE] (indexed site)

    Additives and Cathode Materials for High-Energy Lithium Sulfur Batteries CarbonSulfur Nanocomposites and Additives for High-Energy Lithium Sulfur Batteries Vehicle Technologies ...

  18. Non-Cross-Linked Gel Polymer Electrolytes for Lithium Ion Batteries...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Non-Cross-Linked Gel Polymer Electrolytes for Lithium Ion Batteries Lawrence Berkeley ... have invented nanostructured gel polymer electrolytes for lithium ion batteries. ...

  19. Carbon/Sulfur Nanocomposites and Additives for High-Energy Lithium...

    Energy.gov [DOE] (indexed site)

    CarbonSulfur Nanocomposites and Additives for High-Energy Lithium Sulfur Batteries Additives and Cathode Materials for High-Energy Lithium Sulfur Batteries Protection of Li Anodes ...

  20. Innovative Manufacturing and Materials for Low-Cost Lithium-Ion...

    Energy.gov [DOE] (indexed site)

    for Low-Cost Lithium-Ion Batteries Vehicle Technologies Office Merit Review 2014: Innovative Manufacturing and Materials for Low-Cost Lithium-Ion Batteries Vehicle Technologies ...

  1. Lithium Ion Electrode Production NDE and QC Considerations | Department of

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    Energy Lithium Ion Electrode Production NDE and QC Considerations Lithium Ion Electrode Production NDE and QC Considerations Review of Oak Ridge process and QC activities by David Wood, Oak Ridge National Laboratory, at the EERE QC Workshop held December 9-10, 2013, at the National Renewable Energy Laboratory in Golden, Colorado. Lithium Ion Electrode Production NDE and QC Considerations (1.1 MB) More Documents & Publications Vehicle Technologies Office Merit Review 2014: Roll-to-Roll

  2. Solid lithium ion conducting electrolytes and methods of preparation

    DOEpatents

    Narula, Chaitanya K; Daniel, Claus

    2013-05-28

    A composition comprised of nanoparticles of lithium ion conducting solid oxide material, wherein the solid oxide material is comprised of lithium ions, and at least one type of metal ion selected from pentavalent metal ions and trivalent lanthanide metal ions. Solution methods useful for synthesizing these solid oxide materials, as well as precursor solutions and components thereof, are also described. The solid oxide materials are incorporated as electrolytes into lithium ion batteries.

  3. Celgard US Manufacturing Facilities Initiative for Lithium-ion Battery

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    Separator | Department of Energy Celgard US Manufacturing Facilities Initiative for Lithium-ion Battery Separator Celgard US Manufacturing Facilities Initiative for Lithium-ion Battery Separator 2012 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Program Annual Merit Review and Peer Evaluation Meeting arravt009_es_rumierz_2012_p.pdf (745.7 KB) More Documents & Publications Celgard US Manufacturing Facilities Initiative for Lithium-ion Battery Separator Celgard US

  4. EV Everywhere Batteries Workshop - Next Generation Lithium Ion Batteries

    Energy Saver

    Breakout Session Report | Department of Energy Next Generation Lithium Ion Batteries Breakout Session Report EV Everywhere Batteries Workshop - Next Generation Lithium Ion Batteries Breakout Session Report Breakout session presentation for the EV Everywhere Grand Challenge: Battery Workshop on July 26, 2012 held at the Doubletree OHare, Chicago, IL. report_out-next-generation_li-ion_b.pdf (136.48 KB) More Documents & Publications EV Everywhere Batteries Workshop - Beyond Lithium Ion

  5. Solid lithium ion conducting electrolytes and methods of preparation

    SciTech Connect

    Narula, Chaitanya K.; Daniel, Claus

    2015-11-19

    A composition comprised of nanoparticles of lithium ion conducting solid oxide material, wherein the solid oxide material is comprised of lithium ions, and at least one type of metal ion selected from pentavalent metal ions and trivalent lanthanide metal ions. Solution methods useful for synthesizing these solid oxide materials, as well as precursor solutions and components thereof, are also described. The solid oxide materials are incorporated as electrolytes into lithium ion batteries.

  6. Lithium: Measurement of Young's Modulus and Yield Strength

    SciTech Connect

    Ryan P Schultz

    2002-11-07

    The Lithium Collection Lens is used for anti-proton collection. In analyzing the structural behavior during operation, various material properties of lithium are often needed. properties such as density, coefficient of thermal expansion, thermal conductivity, specific heat, compressability, etc.; are well known. However, to the authors knowledge there is only one published source for Young's Modulus. This paper reviews the results from the testing of Young's Modulus and the yield strength of lithium at room temperature.

  7. Overcharge Protection Prevents Exploding Lithium Ion Batteries - Energy

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Innovation Portal Overcharge Protection Prevents Exploding Lithium Ion Batteries Lawrence Berkeley National Laboratory Contact LBL About This Technology Technology Marketing Summary Berkeley Lab scientists Guoying Chen and Thomas J. Richardson have invented a new type of separator membrane that prevents dangerous overcharge and overdischarge conditions in rechargeable lithium-ion batteries, i.e., exploding lithium ion batteries. This low cost separator, with electroactive polymers

  8. Intermetallic Electrodes Improve Safety and Performance in Lithium-Ion

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Batteries | Argonne National Laboratory Intermetallic Electrodes Improve Safety and Performance in Lithium-Ion Batteries Technology available for licensing: A new class of intermetallic material that can be used as a negative electrode for nonaqueous lithium electrochemical cells and batteries Enhances stability at a reduced cost. Materials operate by lithium insertion, metal displacement reactions, or both. Materials have higher volumetric and gravimetric capacity, and improve battery

  9. Helium Pumping Wall for a Liquid Lithium Tokamak Richard Majeski |

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Princeton Plasma Physics Lab Helium Pumping Wall for a Liquid Lithium Tokamak Richard Majeski This invention is designed to be a subsystem of a device, a tokamak with walls or plasma facing components of liquid lithium. This approach to constructing the lithium-bearing walls of the tokamak allows the wall to fulfill a necessary function -- helium pumping - for which a complex structure was formerly required. The primary novel feature of the invention is that a permeable wall is used to

  10. Vehicle Technologies Office Merit Review 2015: Daikin Advanced Lithium Ion

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    Battery Technology - High Voltage Electrolyte | Department of Energy Daikin Advanced Lithium Ion Battery Technology - High Voltage Electrolyte Vehicle Technologies Office Merit Review 2015: Daikin Advanced Lithium Ion Battery Technology - High Voltage Electrolyte Presentation given by Daikin America at 2015 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about Daikin advanced lithium ion battery technology - high

  11. Vertically Integrated Mass Production of Automotive Class Lithium Ion

    Office of Energy Efficiency and Renewable Energy (EERE) (indexed site)

    Batteries | Department of Energy Vertically Integrated Mass Production of Automotive Class Lithium Ion Batteries Vertically Integrated Mass Production of Automotive Class Lithium Ion Batteries 2012 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Program Annual Merit Review and Peer Evaluation Meeting arravt018_es_alvarez_2012_p.pdf (244.54 KB) More Documents & Publications Vertically Integrated Mass Production of Automotive Class Lithium Ion Batteries Vertically Integrated

  12. A new class of electrochemically and thermally stable lithium salts for lithium battery electrolytes. 3: Synthesis and properties of some lithium organoborates

    SciTech Connect

    Barthel, J.; Buestrich, R.; Carl, E.; Gores, H.J.

    1996-11-01

    Synthesis, analysis, and purification of new lithium salts for lithium batteries, lithium bis[tetrafluoro-1,2-benzene-diolato(2-)-O,O{prime}]borate and lithium bis[2,3-naphthalenediolato(2-)-O,O{prime}]borate are described, and the results of electrochemical studies of these salts and of lithium bis[3-fluoro-1,2-benzenediolato(2-)-O,O{prime}]borate, in propylene carbonate are reported. The effect of the electron-withdrawing substituent fluorine results in an increase of the electrochemical window by 0.1 V/fluorine per one chelate ligand. The slope, which can be calculated from the linear correlation of the highest occupied molecular orbital energies with anodic oxidation potentials is {minus}3.0 eV/V, a value equal to that known for aryl borates and fluoroaryl borates.

  13. Li K-Edge XANES Spectra of Lithium Niobate and Lithium Tantalite

    SciTech Connect

    Mizota, H.; Ito, Y.; Tochio, T.; Handa, K.; Takekawa, S.; Kitamura, K.

    2007-02-02

    The x-ray emission with the single crystal of lithium niobate (LiNbO3) or lithium tantalite (LiTaO3) by thermal changes in a vacuum system is closely concerned with the electronic state of each crystal. Therefore, lithium K-edge x-ray absorption near edge structures (XANES) spectra of these materials were measured in the region from 50 eV to 90 eV by means of total electron yield method (T.E.Y.), using the extremely soft x-ray. Samples were powder of lithium carbonate (Li2CO3) and single crystal of lithium fluoride (LiF), LiNbO3 and LiTaO3 in order to compare the shapes of these XANES spectra. Various peak structures appear in these spectra in the range from 55 eV to 80 eV and each spectrum has different shapes as a result of the difference of bond length and bond angles for the atoms which are in less than 60 nm from the absorbing atom. The relationship between these spectra and the electronic states was discussed by FEFF 8.

  14. METHOD FOR PRODUCING ISOTOPIC METHANES FROM LITHIUM CARBONATE AND LITHIUM HYDRIDE

    DOEpatents

    Frazer, J.W.

    1959-10-27

    A process is descrlbed for the production of methane and for the production of methane containing isotopes of hydrogen and/or carbon. Finely divided lithium hydrlde and litldum carbonate reactants are mixed in intimate contact and subsequently compacted under pressures of from 5000 to 60,000 psl. The compacted lithium hydride and lithium carbenate reactunts are dispised in a gas collecting apparatus. Subsequently, the compact is heated to a temperature in the range 350 to 400 deg C whereupon a solid-solid reaction takes place and gaseous methane is evolved. The evolved methane is contaminated with gaseous hydrogen and a very small amount of CO/sub 2/; however, the desired methane product is separated from sald impurities by well known chemical processes, e.g., condensation in a cold trap. The product methane contalns isotopes of carbon and hydrogen, the Isotopic composition being determined by the carbon isotopes originally present In the lithium carbonate and the hydrogen isotopes originally present in the lithium hydride.

  15. Intermetallic Electrodes Improve Safety and Performance in Lithium...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Intermetallic Electrodes Improve Safety and Performance in Lithium-Ion Batteries Technology available for licensing: A new class of intermetallic material that can be used as a ...

  16. Final Progress Report for Linking Ion Solvation and Lithium Battery

    Office of Scientific and Technical Information (OSTI)

    for Linking Ion Solvation and Lithium Battery Electrolyte Properties Henderson, Wesley 25 ENERGY STORAGE battery, electrolyte, solvation, ionic association battery, electrolyte,...

  17. Analysis of Molecular Clusters in Simulations of Lithium-Ion...

    Office of Scientific and Technical Information (OSTI)

    Journal Article: Analysis of Molecular Clusters in Simulations of Lithium-Ion Battery Electrolytes. Citation Details In-Document Search Title: Analysis of Molecular Clusters in ...

  18. Inward Lithium-Ion Breathing of Hierarchically Porous Silicon...

    Office of Scientific and Technical Information (OSTI)

    Lithium ion battery assembled with this new nanoporous material exhibits high capacity, high power, long cycle life and high coulombic efficiency, which is superior to the current ...

  19. Methods for making anodes for lithium ion batteries (Patent)...

    Office of Scientific and Technical Information (OSTI)

    Data Explorer Search Results Methods for making anodes for lithium ion batteries Title: ... A laminated structure may be prepared from the tape and sintered to produce a porous ...

  20. Negative Electrodes Improve Safety in Lithium Cells and Batteries...

    U.S. Department of Energy (DOE) - all webpages (Extended Search)

    Negative Electrodes Improve Safety in Lithium Cells and Batteries Technology available for licensing: Enhanced stability at a lower cost Lowers cost for enhanced stability ...