UIS应力条件下功率DMOS晶体管的失效机理

The Fourth International Conference on Advanced Semiconductor Devices and Microsystem Pub Date : 2002-12-16 DOI:10.1109/ASDAM.2002.1088541

A. Icaza-Deckelmann, G. Wachutka, J. Krumrey, F. Hirler

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引用次数: 3

摘要

采用电热器件仿真的方法，研究了外电路施加器件电流的UIS应力条件下多单元功率DMOS晶体管的失效机理。结果表明，故障是由双极晶体管结构中每个电池的电流集中引起的。在模拟中，在与应用相关的电流水平内，在此模式形成之前会出现强烈的温度升高。我们的分析表明，高电流密度产生的热量可能导致不稳定，随后器件电流可能集中在器件的单个电池中，从而产生最终的故障。

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Failure mechanism of power DMOS transistors under UIS stress conditions

The failure mechanism of multiple-cell power DMOS transistors under UIS stress conditions, where the device current is imposed by the external circuit, is investigated by means of electrothermal device simulation. The results suggest that the failure is caused by the concentration of the each cell's current in a bipolar transistor structure. In the simulation, a strong temperature rise precedes this pattern formation, within application-relevant current levels. Our analysis shows that the heat generated by the high current density may lead to an instability, and that subsequently the device current is likely to concentrate in one single cell of the device, producing eventual failure.

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The Fourth International Conference on Advanced Semiconductor Devices and Microsystem

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