Title :
GaN transistor reliability and instabilities
Author :
Uren, M.J. ; Kuball, M.
Author_Institution :
H.H. Wills Phys. Lab., Univ. of Bristol, Bristol, UK
Abstract :
GaN based transistors are vulnerable to long time period instabilities as a result of the wide bandgap. In this paper we review the effect of the bulk GaN dopants, which are added to ensure a highly resistive buffer, on the current-collapse which occurs on switching from the off-state to the on-state. The iron doping frequently used in RF devices leads to a trap level in the upper half of the gap which generates a small, reproducible, and straightforwardly modelled current-collapse. On the other hand the carbon doping used in many power devices results in current-collapse which can be large but is strongly impacted by the presence of leaky threading dislocations. A powerful technique to characterise the buffer and extract the vertical leakage in the different layers within a GaN-n-Si power HEMT based on ramping the substrate bias is introduced.
Keywords :
III-V semiconductors; elemental semiconductors; gallium compounds; power HEMT; semiconductor device reliability; semiconductor doping; silicon; wide band gap semiconductors; GaN-Si; RF devices; carbon doping; current-collapse; highly resistive buffer; iron doping; leaky threading dislocations; long time period instabilities; off-state; on-state; power HEMT; power devices; substrate bias; transistor instabilities; transistor reliability; trap level; vertical leakage; wide bandgap; Energy states; Gallium nitride; HEMTs; Iron; Logic gates; MODFETs; Radio frequency;
Conference_Titel :
Advanced Semiconductor Devices & Microsystems (ASDAM), 2014 10th International Conference on
Conference_Location :
Smolenice
Print_ISBN :
978-1-4799-5474-2
DOI :
10.1109/ASDAM.2014.6998665
