Xuan Li, Qian Lou, Hanqing Zhao, Xiaochuan Deng, Bo Zhang
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引用次数: 0
摘要
提出了一种新的SiC沟槽栅IGBT自箝位p屏蔽设计方法。通过在p屏蔽区引入n阱,在发射极侧嵌入增强模式(e模式)PMOS和开基极PNP晶体管。在关断状态下,p -屏蔽层通过e模PMOS的导通被箝位在低电位,对沟槽栅氧化物保持强电场屏蔽作用。在on状态下,P-shield通过n井形成的深孔屏障带电漂浮,增强了注入增强(IE)效果。在高集电极-发射极电压条件下,p -屏蔽通过开基极PNP晶体管的穿孔箝位,有效降低饱和电流。此外,自箝位p屏蔽降低了米勒电容,抑制了开关瞬态时的负栅电容,实现了低开关损耗和高开关速度。因此,自箝位p屏蔽SiC IGBT提供了一种新的设计解决方案,可以同时提高ON-, OFF -和开关性能。
Self-Clamped P-shield SiC Trench IGBT for Low On-State Voltage and Switching Loss
A novel self-clamped P-shield design in SiC trench-gate IGBT is proposed. An enhancement-mode (E-mode) PMOS and open-base PNP transistor are embedded at the emitter side by introducing an N-well into the P-shield region. In OFF -state, the P-shield is clamped at a low potential via the conduction of E-mode PMOS, maintaining a strong electric field shielding effect for trench gate oxide. In ON-state, the P-shield is floating electrically via the deep hole barrier formed by the N-well, enhancing the injection-enhancement (IE) effect. Under high collector-emitter voltage conditions, the P-shield is clamped via the punch-through of the open-base PNP transistor, effectively reducing saturation current. Furthermore, the self-clamped P-shield reduces the Miller capacitance and suppresses the negative gate capacitance during the switching transient, achieving low switching losses and high switching speed. As a result, the self-clamped P-shield SiC IGBT provides a new design solution to improving ON-, OFF -, and switching performance simultaneously.
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