Impact of deep trench isolation on advanced SiGe HBT reliability in radiation environments

2009 IEEE International Reliability Physics Symposium Pub Date : 2009-04-26 DOI:10.1109/IRPS.2009.5173244

S. Phillips, A. Sutton, A. Appaswamy, M. Bellini, J. Cressler, A. Grillo, G. Vizkelethy, P. Dodd, Mike McCurdy, R. Reed, P. Marshall

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引用次数: 11

Abstract

We investigate, for the first time, the impact of deep trench isolation on the total ionizing dose (TID) and single event upset (SEU) tolerance of advanced SiGe HBTs. We employ a combination of 63MeV protons, 10keV X-rays, and 36MeV oxygen ion microbeam irradiation and compare a 3rd generation, high-performance (HP), deep-trench isolated, SiGe BiCMOS platform with its cost-performance (CP) variant without deeptrenches. Although the CP SiGe HBTs are shown to be more susceptible to TID damage, the elevated damage is not attributed to variations in deep trench isolation (DTI), but to spacer oxide differences. CP SiGe HBTs are surprisingly found to offer a potential built-in self-mitigation mechanism for SEU, which is a direct result of the influence of the deep trench isolation on the charge collection dynamics associated with ion strikes. Calibrated, full 3D ion strike TCAD simulations are employed to explain the results, revealing substantial enhancement of radial charge diffusion for structures implemented with little to no deep trench. Mitigation of charge collection events are found to occur for emitter-center strikes for devices with limited/eliminated DTI with the caveat of larger collection for outside-DTI ion strikes.

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深沟隔离对辐射环境下先进SiGe HBT可靠性的影响

我们首次研究了深沟隔离对晚期SiGe HBTs总电离剂量(TID)和单事件干扰(SEU)耐受性的影响。我们采用了63MeV质子、10keV x射线和36MeV氧离子微束辐照的组合，并将第三代高性能(HP)深沟隔离SiGe BiCMOS平台与其无深沟的性价比(CP)版本进行了比较。虽然CP SiGe HBTs更容易受到TID损伤，但损伤的升高不是由于深沟隔离(DTI)的变化，而是由于间隔氧化物的差异。令人惊讶的是，CP SiGe HBTs为SEU提供了一种潜在的内置自我缓解机制，这是深沟隔离对与离子撞击相关的电荷收集动力学影响的直接结果。经过校准的全3D离子冲击TCAD模拟用于解释结果，揭示了在很少或没有深沟槽的结构中径向电荷扩散的显著增强。对于具有有限/消除DTI的设备的发射器中心撞击，发现电荷收集事件会发生缓解，但警告说，对于外部DTI撞击，会产生更大的收集。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2009 IEEE International Reliability Physics Symposium

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