可靠性屏对MOS电荷俘获的影响

Proceedings of the Third European Conference on Radiation and its Effects on Components and Systems Pub Date : 1995-09-18 DOI:10.1109/RADECS.1995.509777

M. Shaneyfelt, P. Winokur, D. Fleetwood, J. Schwank, R. A. Reber

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引用次数: 36

摘要

研究了辐照前高温偏置应力对场氧化晶体管辐射硬度的影响，并将其作为应力温度、时间和偏置的函数。发现应力温度和时间对这些晶体管中辐射引起的电荷积累有显著影响。具体来说，应力温度或时间的增加会导致n沟道场氧化晶体管的I-V特性产生更大的负位移(走向耗尽)。随着应力温度和时间的增加，晶体管I-V特性的变化表明，负责应力效应的机制是热激活的。测得活化能为/spl sim/0.38 eV。在这些晶体管中发现应力偏置对辐射引起的电荷积累没有影响。观察到的应力温度、时间和偏置依赖关系似乎与给定应力期间氢分子的扩散一致。这些结果对硬度保证试验方法的发展具有重要意义。

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Effects of reliability screens on MOS charge trapping

The effects of pre-irradiation elevated-temperature bias stresses on the radiation hardness of field-oxide transistors have been investigated as a function of stress temperature, time, and bias. Both the stress temperature and time are found to have a significant impact on radiation-induced charge buildup in these transistors. Specifically, an increase in either the stress temperature or time causes a much larger negative shift (towards depletion) in the I-V characteristics of the n-channel field-oxide transistors. This increased shift in the transistor I-V characteristics with stress temperature and time suggests that the mechanisms responsible for the stress effects are thermally activated. An activation energy of /spl sim/0.38 eV was measured. The stress bias was found to have no impact on radiation-induced charge buildup in these transistors. The observed stress temperature, time, and bias dependencies appears to be consistent with the diffusion of molecular hydrogen during a given stress period. These results have important implications for the development of hardness assurance test methods.

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Proceedings of the Third European Conference on Radiation and its Effects on Components and Systems

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