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Title: The New World of Lighting: Solid-State Lighting and Beyond.


Abstract not provided.

Publication Date:
Research Org.:
Sandia National Lab. (SNL-NM), Albuquerque, NM (United States)
Sponsoring Org.:
USDOE Office of Energy Efficiency and Renewable Energy (EERE), Building Technologies Program (EE-2J)
OSTI Identifier:
Report Number(s):
DOE Contract Number:
Resource Type:
Resource Relation:
Conference: Proposed for presentation at the Les Eastman Conference held August 2-4, 2016 in Bethlehem, PA.
Country of Publication:
United States

Citation Formats

Tsao, Jeffrey Y. The New World of Lighting: Solid-State Lighting and Beyond.. United States: N. p., 2016. Web.
Tsao, Jeffrey Y. The New World of Lighting: Solid-State Lighting and Beyond.. United States.
Tsao, Jeffrey Y. 2016. "The New World of Lighting: Solid-State Lighting and Beyond.". United States. doi:.
title = {The New World of Lighting: Solid-State Lighting and Beyond.},
author = {Tsao, Jeffrey Y.},
abstractNote = {Abstract not provided.},
doi = {},
journal = {},
number = ,
volume = ,
place = {United States},
year = 2016,
month = 8

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  • Abstract not provided.
  • Dramatic improvement in the efficiency of inorganic and organic light emitting diodes (LEDs and OLEDs) within the last decade has made these devices viable future energy efficient replacements for current light sources. However, both technologies must overcome major technical barriers, requiring significant advances in material science, before this goal can be achieved. Attention will be given to each technology associated with the following major areas of material research: (1) material synthesis, (2) process development, (3) device and defect physics, and (4) packaging. The discussion on material synthesis will emphasize the need for further development of component materials, including substrates andmore » electrodes, necessary for improving device performance. The process technology associated with the LEDs and OLEDs is very different, but in both cases it is one factor limiting device performance. Improvements in process control and methodology are expected to lead to additional benefits of higher yield, greater reliability and lower costs. Since reliability and performance are critical to these devices, an understanding of the basic physics of the devices and device failure mechanisms is necessary to effectively improve the product. The discussion will highlight some of the more basic material science problems remaining to be solved. In addition, consideration will be given to packaging technology and the need for the development of novel materials and geometries to increase the efficiencies and reliability of the devices. The discussion will emphasize the performance criteria necessary to meet lighting applications, in order to illustrate the gap between current status and market expectations for future product.« less
  • No abstract prepared.
  • Once again GaAs MANTECH (with III-Vs Review acting as media sponsor) promises to deliver high quality papers covering all aspects of compound semiconductor manufacturing, with speakers from leading-edge equipment, epiwafer, and device suppliers. Since its launch in 1986, GaAs MANTECH has consistently been one of the highlight events of the conference calendar. Coverage includes all compound-based semiconductors, not just GaAs. With an excellent technical program comprising of almost 80 papers and expanded workshop sessions, the 2003 event should prove the best ever. As in previous years, an Interactive Forum and Ugly Picture Contest will be included. A major attraction willmore » be the associated exhibition, with more than 70 suppliers expected to participate.« less
  • Organic light emitting device (OLEDs) may provide a low-cost, long-lived, and efficient wide area lighting solution if a number of challenges in reliability, cost and efficiency can be overcome. There is a need to develop new TCOs for use as the anode in a bottom-emitting device that do not contain In, have optimal work function, conductivity and visible light transmission properties, possess acceptable stability and possess a high work function to match the deep HOMO of blue OLED HTLs. We report here results from our efforts to scale up sputter deposition on large area substrates (up to 12”x12”) of TCOmore » candidates (including Ga:ZnO and Zn:SnO) identified using combinatorial methods. We present transmission, electrical properties, work function, compositional and structural data for these films. Finally, we have evaluated the use of these materials in OLEDs, and show device performance comparisons between devices fabricated on combinatorial substrates, single composition substrates, and substrates grown at larger scale (up to 12”x12”). Post-operation analysis of the materials using a combination of surface analysis and electron microscopy techniques was performed. The device results demonstrate that we are able to generate substrates with the appropriate work function to reduce the operating voltage of blue phosphorescent OLEDs compared to commercial ITO, which we ascribe to improved work function-HOMO energy matching leading to more efficient charge injection into the device HTL.« less