Title :
Nanocrystalline Diamond for near Junction Heat Spreading in GaN Power HEMTs
Author :
Anderson, Travis J. ; Hobart, Karl D. ; Tadjer, Marko J. ; Koehler, Andrew D. ; Feygelson, Tatyana I. ; Hite, Jennifer K. ; Pate, Bradford B. ; Kub, Francis J. ; Eddy, Charles R.
Author_Institution :
Naval Res. Lab., Washington, DC, USA
Abstract :
Reduced performance in Gallium Nitride (GaN)-based high electron mobility transistors (HEMTs) as a result of self-heating has been well-documented. A new approach, termed "gate after diamond," is shown to improve the thermal budget of the deposition process and enable large-area diamond without degrading the gate metal. Nanocrystalline (NCD)-capped devices had 20% lower channel temperature at equivalent power dissipation. Improved electrical characteristics were observed, notably improved on-resistance and breakdown voltage, and reduced gate leakage. Further refinements to the NCD growth process have enabled deposition directly on the GaN surface. Pulsed I-V measurements indicate a comparable passivation effect to conventional SiNx-capped devices.
Keywords :
III-V semiconductors; diamond; electric breakdown; gallium compounds; nanostructured materials; passivation; power HEMT; silicon compounds; wide band gap semiconductors; C; GaN; GaN power HEMT; GaN surface; NCD-capped devices; SiNx; breakdown voltage; deposition process; electrical characteristics; equivalent power dissipation; gallium nitride; gate after diamond; gate leakage; gate metal; high electron mobility transistors; large-area diamond; nanocrystalline diamond; nanocrystalline-capped devices; near junction heat spreading; passivation effect; pulsed I-V measurements; self-heating; thermal budget; Diamonds; Gallium nitride; HEMTs; Heating; Logic gates; MODFETs; Temperature measurement;
Conference_Titel :
Compound Semiconductor Integrated Circuit Symposium (CSICS), 2013 IEEE
Conference_Location :
Monterey, CA
DOI :
10.1109/CSICS.2013.6659241
