Title :
Reduction of carbon proximity effects by including AIGaN back barriers in HEMTs on free-standing GaN
Author :
Kaun, Stephen W. ; Wong, Man Hoi ; Lu, Jun ; Mishra, Umesh K. ; Speck, James S.
Author_Institution :
Mater. & ECE Depts., Univ. of California, Santa Barbara, Santa Barbara, CA, USA
Abstract :
High-electron-mobility transistor (HEMT) structures were regrown by molecular beam epitaxy on GaN-on-SiC templates and free-standing (FS) GaN substrates with very low threading dislocation density (TDD). To ensure a high buffer breakdown voltage, the thickness of the unintentionally doped (UID) GaN buffer layer, dUID, was reduced to 200 nm for the HEMTs regrown on FS GaN. A reduction in TDD entailed an increase in the three-terminal breakdown voltage for passivated HEMTs. With a low dUID, the proximity effects of the carbon-doped GaN buffer were evident. A power-added efficiency (PAE) of 37% and continuous-wave power output (Pout) of 4.2 W/mm were measured at 4 GHz with a drain bias of 40 V for a HEMT on FS GaN without a back barrier. By including a 5 nm Al0.3Ga0.7N back barrier, PAE and Pout improved to 50% and 6.7 W/mm, respectively, at a drain bias of 40 V.
Keywords :
III-V semiconductors; aluminium compounds; electric breakdown; gallium compounds; high electron mobility transistors; molecular beam epitaxial growth; silicon compounds; wide band gap semiconductors; Al0.3Ga0.7N; FS substrates; GaN-on-SiC templates; HEMT structures; PAE; SiC; TDD; UID; back barriers; carbon proximity effects reduction; efficiency 37 percent; free-standing substrates; frequency 4 GHz; high buffer breakdown voltage; high-electron-mobility transistor; molecular beam epitaxy; power-added efficiency; size 5 nm; three-terminal breakdown voltage; unintentionally doped buffer layer; very low threading dislocation density; voltage 40 V;
Journal_Title :
Electronics Letters
DOI :
10.1049/el.2013.1723
