20kv, 2cm2, 4H-SiC栅极关断晶闸管,用于先进的脉冲功率应用

Lin Cheng, A. Agarwal, C. Capell, M. O'loughlin, E. van Brunt, K. Lam, J. Richmond, A. Burk, J. Palmour, H. O’Brien, A. Ogunniyi, C. Scozzie
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引用次数: 48

摘要

基于宽禁带半导体如碳化硅(SiC)的高压功率器件由于其在高温应用中优于硅的材料特性而备受关注。在高压SiC功率器件中,4H-SiC栅极关断晶闸管(GTO)具有出色的电流处理能力,非常高的电压阻断能力和快速关断能力。与基于igbt的开关相比,4H-SiC GTO还具有更低的正向压降,从而在正常工作时产生更低的损耗。它是脉冲功率应用的理想开关,需要高开通di/dt。为了在SiC中实现大于20 kV的阻断能力,需要一个厚的漂移外延层(> 160 μm),并提高载流子寿命(5 ~ 10 μs),以获得全电导率调制。在本文中,我们首次报道了我们最近开发的1×2 cm2, 20 kV, 4H-SiC p-GTO,使用160 μm, 2×1014/cm3掺杂的p型漂移层。该装置的有效导通面积为0.53 cm2。由于高压实验装置的限制,在漏电流为1 μA时,4H-SiC p-GTO的片上栅极阻断电压为19.9 kV,对应于室温下一维(1D)最大电场为~ 1.5 MV/cm。为了在高电流水平(bbb100 A/cm2)下测量这种大面积,4H-SiC, p-GTO,使用泰克371曲线示踪器在脉冲模式下评估该器件的正向特性。在栅极电流为0.35 A,高电流为300 A/cm2 ~ 400 A/cm2时,差分比导通电阻为11 MΩ-cm2。更多的结果和讨论将在会议上提出。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
20 kV, 2 cm2, 4H-SiC gate turn-off thyristors for advanced pulsed power applications
The development of high-voltage power devices based on wide bandgap semiconductor such as silicon carbide (SiC) has attracted great attention due to its superior material properties over silicon for high-temperature applications. Among the high-voltage SiC power devices, the 4H-SiC gate turn-off thyristor (GTO) offers excellent current handling, very high voltage blocking, and fast turn-off capabilities. The 4H-SiC GTO also exhibits lower forward voltage drop than the IGBT-based switches, resulting in lower losses during normal operation. It is an ideal switch for pulsed power applications that require high turn-on di/dt. In order to achieve a blocking capability of or greater than 20 kV in SiC, a thick drift epi-layer (> 160 μm) with an improved carrier lifetime (5 ~ 10 μs) is necessary to obtain a full conductivity modulation. In this paper, for the first time to our knowledge, we report our recently developed 1×2 cm2, 20 kV, 4H-SiC p-GTO using a 160 μm, 2×1014/cm3 doped, p-type drift layer. The active conducting area of the device is 0.53 cm2. Due to the limitations of the high-voltage test set-up, the 4H-SiC p-GTO showed an on-wafer gate-to-anode blocking voltage of 19.9 kV at a leakage current of 1 μA, which corresponds to a one-dimensional (1D) maximum electrical field of ~ 1.5 MV/cm at room-temperature. To measure this large area, 4H-SiC, p-GTO at high current levels (> 100 A/cm2), the forward characteristics of the device were evaluated using a Tektronix 371 curve tracer in pulse mode. A differential specific on-resistance of 11 MΩ-cm2 was obtained at a gate current of 0.35 A and a high current of 300 A/cm2 ~ 400 A/cm2. More results and discussion will be presented at the conference.
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