Title :
Microfabricated Thermally Isolated Low Work-Function Emitter
Author :
Jae-Hyung Lee ; Bargatin, Igor ; Vancil, Bernard K. ; Gwinn, Thomas O. ; Maboudian, Roya ; Melosh, Nicholas A. ; Howe, R.T.
Author_Institution :
Stanford Univ., Stanford, CA, USA
Abstract :
In this paper, we report low work function mechanically and thermally robust microfabricated thermionic emitters. Conformal deposition of polycrystalline-silicon carbide (poly-SiC) was used to form stiff suspension legs with U-shaped cross sections, which increased the out-of-plane rigidity and helped to maintain a micrometer-scale gap between emitter and collector. The structurally robust poly-SiC suspended structure was coated with a thin tungsten layer to improve adhesion of a work function lowering coating (BaO/SrO/CaO). The measured emitter work function was 1.2 eV and emission current density was >0.1 A/cm2, which are promising for applications such as thermionic energy converters.
Keywords :
barium compounds; calcium compounds; microfabrication; silicon compounds; strontium compounds; thermionic cathodes; thermionic conversion; thermionic emission; tungsten; wide band gap semiconductors; work function; BaO-SrO-CaO; SiC; U-shaped cross sections; W; collector; conformal deposition; electron volt energy 1.2 eV; emission current density; low work function mechanically microfabricated thermionic emitters; microfabricated thermally isolated low work-function emitter; micrometer-scale gap; out-of-plane rigidity; polycrystalline-silicon carbide; stiff suspension legs; structurally robust suspended structure; thermionic cathode; thermionic energy converters; thin tungsten layer; Barium; Coatings; Fabrication; Heating; Silicon; Temperature measurement; Tungsten; Thermionic emitter; barium coating; barium oxide coating; energy conversion efficiency; silicon carbide; silicon carbide.; thermionic cathode; work function lowering;
Journal_Title :
Microelectromechanical Systems, Journal of
DOI :
10.1109/JMEMS.2014.2307882
