亞洲知識產權資訊網為知識產權業界提供一個一站式網上交易平台，協助業界發掘知識產權貿易商機，並與環球知識產權業界建立聯繫。無論你是知識產權擁有者正在出售您的知識產權，或是製造商需要購買技術以提高操作效能，又或是知識產權配套服務供應商，你將會從本網站發掘到有用的知識產權貿易資訊。

返回搜索結果

Perovskites as Ultralow Work Function Cathode Materials

技術優勢: Lower work function and more stable barium adsorption than existing technologies (e.g., tungsten or scandate surfaces) Potential for significantly extended cathode lifetime and higher electron emission levels

技術應用: SrVO3 (with or without Ba doping) for ultralong lifetime, highly emissive cathode materialThermionic emission technologiesHigh power vacuum electronic devicesHigh power microwave components and systems

詳細技術說明: Electron emission cathode materials are found in high power electron beam devices used in defense, scientific research and communications applications as well as thermionic energy conversion technologies. Suitable electron source materials desirably exhibit a low work function, stability at high temperatures, and sufficient conductivity to sustain the desired emission current.Leading thermionic electronic emitters composed of refractory metals like tungsten – while stable and good conductors – must be coated with an oxide to lower the work function. These coatings are volatile and degrade over time, limiting the lifetime and efficiency of devices. Alternatively, perovskite materials are of interest because they possess desirably low work functions and may eliminate the need for a volatile surface layer. Determining the work function values for perovskites is essential for applications involving electron transport at interfaces or surfaces, including solar cells, electrocatalysts, conducting oxide electronics, Schottky barriers and vacuum electron emitters as well as thermionic energy conversion.Using high-throughput computing and informatics to screen thousands of candidates, UW–Madison researchers have identified a perovskite oxide, SrVO3, with a lower predicted work function than current state-of-the-art cathodes. SrVO3 exhibited one of the lowest calculated work functions (1.86 eV) out of 18 perovskite materials investigated (~ 40 compositionally distinct surfaces). Non-volatile barium doping was used to further lower the work function (1.07 eV) and was more stable than on tungsten or scandium surfaces, indicating that Ba will reside on SrVO3 orders of magnitude longer than on other widely explored thermionic cathode material surfaces.

*Abstract: The Wisconsin Alumni Research Foundation (WARF) is seeking commercial partners interested in developing perovskite materials newly identified for use in high power vacuum electronics, microwave technologies and thermionic energy conversion.

*Principal Investigation: Name: Dane Morgan
Department:

Name: Ryan Jacobs
Department:

Name: John Booske
Department:

其他: Read a news story about this technology.
http://news.wisc.edu/new-material-picked-by-computers-could-boost-power-of-vacuum-electronics/

For information about perovskite-based cathodes for solid oxide fuel cells and related technologies, see WARF reference number P160222US01.
http://www.warf.org/technologies/summary/P160022US01.cmsx

國家/地區: 美國

欲了解更多信息，請點擊這裡