通过基于物理的设备模拟的电气测量的相互关联:连接电气和结构特性

A. Padovani, L. Larcher, L. Vandelli, M. Bertocchi, R. Cavicchioli, D. Veksler, G. Bersuker
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引用次数: 0

摘要

我们提出了一个全面的模拟框架来解释现代半导体器件中栅极介电堆材料表征和可靠性分析常用的电气特性(I-V, C-V, G-V,电荷泵浦,BTI, CVS, RVS,…)。通过考虑控制电荷通过电介质传输的物理过程(例如,缺陷位置的载流子捕获/去捕获,缺陷产生等),使用基于材料特性[1],[2]的新方法进行建模,模拟提供了电学测量数据与电介质堆栈中特定原子缺陷之间的独特联系。在这种方法中,软件允许通过预应力电气参数(IV, CV, BTI)的交叉相关测量准确的缺陷光谱。然后,通过模拟应力引起的泄漏电流(SILC)和随时间变化的介电退化趋势,利用这些数据来预测堆栈的可靠性,从而证明该工具作为技术表征/优化基准的能力。
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Cross-correlation of electrical measurements via physics-based device simulations: Linking electrical and structural characteristics
We present a comprehensive simulation framework to interpret electrical characteristics (I-V, C-V, G-V, Charge-Pumping, BTI, CVS, RVS, ...) commonly used for material characterization and reliability analysis of gate dielectric stacks in modern semiconductor devices. By accounting for the physical processes controlling charge transport through the dielectric (e.g. carrier trapping/de-trapping at the defect sites, defect generation, etc.), which is modeled using a novel approach based of material characteristics [1], [2], the simulations provide a unique link between the electrical measurements data and specific atomic defects in the dielectric stack. Within this methodology, the software allows an accurate defect spectroscopy by cross-correlating measurements of pre-stress electrical parameters (IV, CV, BTI). These data are then used to project the stack reliability through the simulations of stress-induced leakage current (SILC) and time-dependent dielectric degradation trends, demonstrating the tool capabilities as a technology characterization/optimization benchmark.
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