Title :
Thermal Modeling of High Power GaN-on-Diamond HEMTs Fabricated by Low-Temperature Device Transfer Process
Author :
Chu, K.K. ; Yurovchak, T. ; Chao, P.C. ; Creamer, C.T.
Author_Institution :
Microelectron. Center, BAE Syst., Nashua, NH, USA
Abstract :
We report on a novel fabrication process of GaN-on-Diamond high electron mobility transistors (HEMTs) and its resulting thermal performance enhancement over conventional GaN-on-SiC technology. In this process, GaN devices are first fabricated on their epitaxial substrate (e.g. sapphire or SiC) before being removed from the original substrate and bonded onto a high-thermal-conductivity diamond substrate at low temperature. Process flow and technology progress is described. Finite-element thermal analysis is performed to quantify the thermal performance improvement of our GaN-on-Diamond design over conventional GaN-on-SiC technology together with the impact of thermal boundary resistance at the GaN/diamond bonding interface.
Keywords :
III-V semiconductors; finite element analysis; gallium compounds; power HEMT; power semiconductor devices; semiconductor device manufacture; semiconductor device models; thermal analysis; wide band gap semiconductors; epitaxial substrate; finite-element thermal analysis; high electron mobility transistors; high power GaN-on-diamond HEMT; high-thermal-conductivity diamond substrate; low-temperature device transfer process; thermal boundary resistance; thermal modeling; Diamonds; Gallium nitride; Junctions; Performance evaluation; Substrates; Temperature sensors; Thermal resistance;
Conference_Titel :
Compound Semiconductor Integrated Circuit Symposium (CSICS), 2013 IEEE
Conference_Location :
Monterey, CA
DOI :
10.1109/CSICS.2013.6659246
