Title :
High Breakdown Voltage and Low Thermal Effect Micromachined AlGaN/GaN HEMTs
Author :
Hsien-Chin Chiu ; Hsiang-Chun Wang ; Chih-Wei Yang ; Yue-Ming Hsin ; Jen-Inn Chyi ; Chang-Luen Wu ; Chian-Sern Chang
Author_Institution :
Dept. of Electron. Eng., Chang Gung Univ., Kwei-shan, Taiwan
Abstract :
This work develops a thermally stable micromachined AlGaN/GaN high-electron mobility transistor (HEMT) with an enhanced breakdown voltage. After removal of the Si substrate beneath the HEMT, a 300-nm SiO2 and a 20-μm copper layer are deposited to form the GaN-on-insulator (G.O.I.) structure. The self-heating at high current that is exhibited by GaN HEMTs that are by previously developed full substrate removal methods is eliminated. The need for complicated substrate-transfer technology is also eliminated, increasing chip package yield. The low frequency noise measurement results also demonstrate that the trap density of the buffer/transition layer is reduced by the removal of the substrate and micromachining of the HEMTs.
Keywords :
III-V semiconductors; aluminium compounds; buffer layers; copper; elemental semiconductors; gallium compounds; high electron mobility transistors; micromachining; semiconductor device breakdown; silicon compounds; wide band gap semiconductors; AlGaN-GaN; Cu; G.O.I. structure; GaN-on-insulator structure; HEMTs; SiO2; buffer layer; chip package yield; copper layer; full substrate removal methods; high breakdown voltage; high-electron mobility transistor; low frequency noise measurement; low thermal effect; self-heating; size 20 mum; size 300 nm; substrate-transfer technology; thermally stable micromachining; transition layer; trap density; Aluminum gallium nitride; Gallium nitride; HEMTs; MODFETs; Silicon; Standards; Substrates; AlGaN/GaN HEMT; Micromachined technology; breakdown voltage; buffer layer traps; low frequency noise;
Journal_Title :
Device and Materials Reliability, IEEE Transactions on
DOI :
10.1109/TDMR.2014.2317001
