Scholarly Works, Center for Power Electronics Systems
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Browsing Scholarly Works, Center for Power Electronics Systems by Content Type "Conference proceeding"
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- 2 kV, 0.7 mΩ·cm2 Vertical Ga2O3 Superjunction Schottky Rectifier with Dynamic RobustnessQin, Yuan; Porter, Matthew; Xiao, Ming; Du, Zhonghao; Zhang, Hongming; Ma, Yunwei; Spencer, Joseph; Wang, Boyan; Song, Qihao; Sasaki, Kohei; Lin, Chia-Hung; Kravchenko, Ivan; Briggs, Dayrl P.; Hensley, Dale K.; Tadjer, Marko; Wang, Han; Zhang, Yuhao (IEEE, 2023)We report the first experimental demonstration of a vertical superjunction device in ultra-wide bandgap (UWBG) Ga2O3. The device features 1.8 μm wide, 2×1017 cm-3 doped n-Ga2O3 pillars wrapped by the charge-balanced p-type nickel oxide (NiO). The sidewall NiO is sputtered through a novel self-align process. Benefitted from the high doping in Ga2O3, the superjunction Schottky barrier diode (SJ-SBD) achieves a ultra-low specific on-resistance (RON,SP) of 0.7 mΩ·cm2 with a low turn-on voltage of 1 V and high breakdown voltage (BV) of 2000 V. The RON,SP~BV trade-off is among the best in all WBG and UWBG power SBDs. The device also shows good thermal stability with BV > 1.8 kV at 175 oC. In the unclamped inductive switching tests, the device shows a dynamic BV of 2.2 kV and no degradation under 1.7 kV repetitive switching, verifying the fast acceptor depletion in NiO under dynamic switching. Such high-temperature and switching robustness are reported for the first time in a heterogeneous superjunction. These results show the great potential of UWBG superjunction power devices.
- Gate Lifetime of P-Gate GaN HEMT in Inductive Power SwitchingWang, Bixuan; Zhang, Ruizhe; Wang, Hengyu; He, Quanbo; Song, Qihao; Li, Qiang; Udrea, Florin; Zhang, Yuhao (IEEE, 2023-06)The small gate overvoltage margin is a crucial concern in applications of GaN Schottky-type p-gate high electron mobility transistors (SP-HEMTs). The parasitic inductance of the gate loop can induce repetitive gate-voltage (VG) spikes during the device turn-on transients. However, the gate lifetime of the GaN SP-HEMTs under VG overshoot in power converters still remains unclear. We fill this gap by developing a new circuit method to measure the gate switching lifetime. The method features several capabilities: 1) LC-resonance-like VG overshoots with pulse width down to 20 ns and dVG/dt up to 2 V/ns; 2) adjustable power loop condition including the drain-source grounded (DSG) as well as the hard switching (HSW); and 3) repetitive switching test at an adjustable switching frequency (fSW). We use this method to test over 150 devices, and found that the gate lifetimes under a certain peak magnitude of VG overshoot (VG(PK)) can be fitted by both Weibull and Lognormal distributions. The gate lifetime is primarily determined by the number of switching cycles and is higher under the HSW than under the DSG conditions. Finally, the max VG(PK) for 10-year gate lifetime is predicted under different fSW in both DSG and HSW conditions. The results provide direct reference for GaN SP-HEMT’s converter applications and a new method for the device gate qualification.