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Title: Final Report: Characterization of Hydrogen Adsorption in Carbon-Based Materials by NMR

Technical Report ·
DOI:https://doi.org/10.2172/1018531· OSTI ID:1018531
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In support of DOE/EERE's Fuel Cell Technologies Program Hydrogen Sorption Center of Excellence (HSCoE), UNC conducted Nuclear Magnetic Resonance (NMR) measurements that contributed spectroscopic information as well as quantitative analysis of adsorption processes. While NMR based Langmuir isotherms produce reliable H2 capacity measurements, the most astute contribution to the center is provided by information on dihydrogen adsorption on the scale of nanometers, including the molecular dynamics of hydrogen in micropores, and the diffusion of dihydrogen between macro and micro pores. A new method to assess the pore width using H2 as probe of the pore geometry was developed and is based on the variation of the observed chemical shift of adsorbed dihydrogen as function of H2 pressure. Adsorbents designed and synthesized by the Center were assessed for their H2 capacity, the binding energy of the adsorption site, their pore structure and their ability to release H2. Feedback to the materials groups was provided to improve the materials’ properties. To enable in situ NMR measurements as a function of H2 pressure and temperature, a unique, specialized NMR system was designed and built. Pressure can be varied between 10-4 and 107 Pa while the temperature can be controlled between 77K and room temperature. In addition to the 1H investigation of the H2 adsorption process, NMR was implemented to measure the atomic content of substituted elements, e.g. boron in boron substituted graphitic material as well as to determine the local environment and symmetry of these substituted nuclei. The primary findings by UNC are the following: • Boron substituted for carbon in graphitic material in the planar BC3 configuration enhances the binding energy for adsorbed hydrogen. • Arrested kinetics of H2 was observed below 130K in the same boron substituted carbon samples that combine enhanced binding energy with micropore structure. • Hydrogen storage material made from activated PEEK is well suited for hydrogen storage due to its controlled microporous structure and large surface area. • A new porosimetry method for evaluating the pore landscape using H2 as a probe was developed. 1H NMR can probe the nanoscale pore structure of synthesized material and can assess the pore dimension over a range covering 1.2 nm to 2.5 nm, the size that is desired for H2 adsorption. • Analysis of 1H NMR spectra in conjunction with the characterization of the bonding structure of the adsorbent by 13C NMR distinguishes between a heterogeneous and homogeneous pore structure as evidenced by the work on AX21 and activated PEEK. • Most of the sorbents studied are suited to hydrogen storage at low temperature (T < 100K). Of the materials investigated, only boron substituted graphite has the potential to work at higher temperatures if the boron content in the favorable planar BC3 configuration that actively contributes to adsorption can be increased.

Research Organization:
Univ. of North Carolina, Chapel Hill, NC (United States)
Sponsoring Organization:
USDOE Office of Energy Efficiency and Renewable Energy (EERE), Transportation Office. Fuel Cell Technologies Office. Hydrogen Sorption Center of Excellence (HSCoE)
DOE Contract Number:
FC36-05GO15081
OSTI ID:
1018531
Report Number(s):
Final Report: Characterization of Hydrogen Adsorption in Carbon-Based Materials by NMR; GO15081; TRN: US1103550
Country of Publication:
United States
Language:
English

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Related Subjects

08 HYDROGEN
36 MATERIALS SCIENCE
ADSORBENTS
ADSORPTION
BINDING ENERGY
BORON
CARBON
CHEMICAL SHIFT
DIFFUSION
FUEL CELLS
GEOMETRY
GRAPHITE
HYDROGEN
HYDROGEN STORAGE
ISOTHERMS
KINETICS
NMR SPECTRA
NUCLEAR MAGNETIC RESONANCE
NUCLEI
PORE STRUCTURE
SORPTION
SURFACE AREA
SYMMETRY
Hydrogen adsorption
Sorbent Materials
Nuclear Magnetic Resonance
Adsorption
Langmuir