Browsing by Author "Udrea, Florin"

Now showing 1 - 5 of 5
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    1 kV Self-Aligned Vertical GaN Superjunction Diode
    Ma, Yunwei; Porter, Matthew; Qin, Yuan; Spencer, Joseph; Du, Zhonghao; Xiao, Ming; Wang, Yifan; Kravchenko, Ivan; Briggs, Dayrl P.; Hensley, Dale K.; Udrea, Florin; Tadjer, Marko; Wang, Han; Zhang, Yuhao (IEEE, 2024-01)
    This work demonstrates vertical GaN superjunction (SJ) diodes fabricated via a novel self-aligned process. The SJ comprises n-GaN pillars wrapped by the charge-balanced p-type nickel oxide (NiO). After the NiO sputtering around GaN pillars, the self-aligned process exposes the top pillar surfaces without the need for additional lithography or a patterned NiO etching which is usually difficult. The GaN SJ diode shows a breakdown voltage (B V) of 1100 V, a specific on-resistance ( RON) of 0.4 mΩ⋅ cm2, and a SJ drift-region resistance ( Rdr) of 0.13 mΩ⋅ cm2. The device also exhibits good thermal stability with B V retained over 1 kV and RON dropped to 0.3 mΩ⋅ cm2 at 125oC . The trade-off between B V and Rdr is superior to the 1D GaN limit. These results show the promise of vertical GaN SJ power devices. The self-aligned process is applicable for fabricating the heterogeneous SJ based on various wide- and ultra-wide bandgap semiconductors.
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    Dynamic Gate Breakdown of p-Gate GaN HEMTs in Inductive Power Switching
    Wang, Bixuan; Zhang, Ruizhe; Wang, Hengyu; He, Quanbo; Song, Qihao; Li, Qiang; Udrea, Florin; Zhang, Yuhao (IEEE, 2023-02)
    We employ a new circuit method to characterize the gate dynamic breakdown voltage (BVdyn) of Schottky-type p-gate GaN HEMTs in power converters. Different from prior pulse I-V and DC stress tests, this method features a resonance-like gate ringing with the pulse width down to 20 ns and an inductive switching concurrently in the drain-source loop. At the increased pulse width, the gate BVdyn shows a decrease and then saturation at 21~22 V. Moreover, the gate BVdyn increases with temperature and is higher under the hard switching than that under the drain-source grounding condition. In the 400 V hard switching at 150 oC, the gate BVdyn reaches 27.5 V. Such impact of the drain switching locus and temperature on the gate BVdyn is not seen in Si and SiC power transistors tested in the same setup. These results are explained by a physics model that accounts for the electrostatics in the p-GaN gate stack in hard switching and at high temperatures. This work unveils new physics critical to the gate robustness of p-gate GaN HEMTs and manifest the necessity of the gate robustness evaluation in inductive switching conditions.
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    Gate Lifetime of P-Gate GaN HEMT in Inductive Power Switching
    Wang, 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.
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    Gate Robustness and Reliability of P-Gate GaN HEMT Evaluated by a Circuit Method
    Wang, Bixuan; Zhang, Ruizhe; Song, Qihao; Wang, Hengyu; He, Quanbo; Li, Qiang; Udrea, Florin; Zhang, Yuhao (IEEE, 2024-01)
    The small gate overvoltage margin is a key reliability concern of the GaN Schottky-type p-gate high electron mobility transistor (GaN SP-HEMT). Current evaluation of gate reliability in GaN SP-HEMTs relies on either the DC bias stress or pulse I-V method, neither of which resembles the gate voltage (VGS) overshoot waveform in practical converters. This work develops a new circuit method to characterize the gate robustness and reliability in GaN SP-HEMTs, which features a resonance-like VGS ringing with pulse width down to 20 ns and an inductive switching concurrently in the drain-source loop. Using this method, the gate's single-pulse failure boundary, i.e., dynamic gate breakdown voltage (BVDYN), is first obtained under the hard switching (HSW) and drain-source grounded (DSG) conditions. The gate's switching lifetime is then tested under the repetitive VGS ringing, and the number of switching cycles to failure (SCTF#) is fitted by Weibull or Lognormal distributions. The SCTF# shows a power law relation with the VGS peak value and little dependence on the switching frequency. More interestingly, the gate's BVDYN and lifetime are both higher in HSW than those in DSG, as well as at higher temperatures. Such findings, as well as the gate degradation behaviors in a prolonged overvoltage stress test, can be explained by the time-dependent Schottky breakdown mechanism. The gate leakage current is found to be the major precursor of gate degradation. At 125 oC and 100 kHz, the VGS limits for a 10-year lifetime are projected to be ∼6 V and ∼10 V under the DSG and HSW conditions, respectively. These results provide a new qualification method and reveal new physical insights for gate reliability and robustness in p-gate GaN HEMTs.
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    Multidimensional device architectures for efficient power electronics
    Zhang, Yuhao; Udrea, Florin; Wang, Han (Springer Nature, 2022-11-17)
    Power semiconductor devices are key to delivering high-efficiency energy conversion in power electronics systems, which is critical in efforts to reduce energy loss, cut carbon dioxide emissions and create more sustainable technology. Although the use of wide or ultrawide-bandgap materials will be required to develop improved power devices, multidimensional architectures can also improve performance, regardless of the underlying material technology. In particular, multidimensional device architectures—such as superjunction, multi-channel and multi-gate technologies—can enable advances in the speed, efficiency and form factor of power electronics systems. Here we review the development of multidimensional device architectures for efficient power electronics. We explore the rationale for using multidimensional architectures and the different architectures available. We also consider the performance limits, scaling and material figure of merits of the architectures, and identify key technological challenges that need to be addressed to realize the full potential of the approach.