R. Singh, Stoyan Jeliazkov, B. Grummel, S. Sundaresan
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引用次数: 4
摘要
在10 kV SiC bjt上测得集电极阻断电压为10.5 kV(为理论雪崩极限的91%,为125 V/μm),导通电阻为110 mΩ-cm2,接近单极极限94 mΩ-cm2,电流增益高达75。在同一晶圆上制备的单片达灵顿连接bjt的电流增益高达3400,并且在饱和区和明显的准饱和区显示出类似Si bjt的输出特性。在直流链路电压为5kv,集电极电流为8a的情况下进行的开关测量表明,在导通期间集电极电流上升时间低至30ns,在关断期间集电极电压恢复时间低至100ns。从开关瞬态中提取的导通和关断能量分别为4.2 mJ和1.6 mJ,比6.5 kV Si igbt的相应开关能量小19和25倍。当集电极偏压为4500v时,10kv BJT表现出温度不变性,耐受时间超过20 μs。泄漏电流<;1μA(系统极限),即使在高温下5000 V直流集电极偏压下工作234小时。
Switching and robustness analysis of 10 kV SiC BJTs
Collector-Emiter blocking voltages of 10.5 kV (91% of theoretical avalanche limit and 125 V/μm), on-resistance of 110 mΩ-cm2, which is close to the unipolar limit of 94 mΩ-cm2, and current gain as high as 75 are measured on 10 kV SiC BJTs. Monolithic Darlington-connected BJTs fabricated on the same wafer yield current gains as high as 3400, and show Si BJT-like output characteristics in the saturation region and a distinct quasi-saturation region. Switching measurements performed at a DC link voltage of 5 kV and collector current of 8 A feature a collector current rise time as low as 30 ns during turn-on and collector voltage recovery time as low as 100 ns during turn-off. Very low turn-on and turn-off switching energies of 4.2 mJ and 1.6 mJ, respectively, are extracted from the switching transients, which are 19 and 25 times smaller than the corresponding switching energies reported on 6.5 kV Si IGBTs. When turned-on to a short-circuited load at a collector bias of 4500 V, the 10 kV BJT shows a temperature-invariant, withstand time in excess of 20 μs. Leakage currents <; 1μA (system limit) are measured, even after 234 hours of operation under a DC collector bias of 5000 V at elevated temperatures.
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