电磁场应力诱导SiGe HBT降解的表征与仿真

2009 16th IEEE International Symposium on the Physical and Failure Analysis of Integrated Circuits Pub Date : 2009-07-06 DOI:10.1109/IPFA.2009.5232729

A. Alaeddine, M. Kadi, K. Daoud, B. Beydoun, D. Blavette

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引用次数: 4

摘要

对SiGe异质结双极晶体管(hbt)在电磁场侵袭下的可靠性进行了研究。我们展示了电磁应力下电流增益衰减的实验证据。器件的退化是由于热载流子(HC)注入到发射极-基极间隔氧化物中，引起了生成/重组陷阱中心，并导致了过量的非理想基极电流。基于HBT横截面的二维模拟已经被用来帮助理解与这种降解机制相关的器件物理。由于在发射基间隔氧化物处引入表面复合中心，产生了与提取的实验数据一致的非理想基电流。模拟结果表明，应力时间与Si/SiO2界面损伤引起的复合速率有较强的相关性。

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Characterization and simulation of SiGe HBT degradation induced by electromagnetic field stress

A new reliability study in SiGe Heterojunction Bipolar Transistors (HBTs) is investigated resulting from electromagnetic field aggression. We demonstrate experimental evidence of current gain degradation during electromagnetic stress. The device degradation is due to the Hot Carrier (HC) injected into the emitter- base spacer oxide, which induces Generation/Recombination trap centers, and leads to excess non-ideal base currents. Two-dimensional simulations, based on the HBT cross section, have been used to help understand the device physics associated with this degradation mechanism. As a consequence of introducing the surface recombination centers at the emitter-base spacer oxide, a non-ideal base current arises in agreement with the experimental data extracted. Simulation results show a strong correlation between stress time and recombination rate induced by the Si/SiO2 interface damage.

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2009 16th IEEE International Symposium on the Physical and Failure Analysis of Integrated Circuits

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