Low frequency noise modeling of SOI MOSFETs using Green's function approach

2011 21st International Conference on Noise and Fluctuations Pub Date : 2011-06-12 DOI:10.1109/ICNF.2011.5994339

J. Elhusseini, F. Martinez, J. Armand, M. Bawedin, M. Valenza, F. Pascal, R. Ritzenthaler, F. Lime, B. Iñíguez, O. Faynot

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引用次数: 1

Abstract

In this paper, we present a new numerical model of the inversion charge power spectral density in FDSOI MOSFET devices with ultra thin body. Unlike previous classical models, we don't use the equivalent concept which relates the fluctuation of the oxide charge to the flat-band voltage fluctuation. Localized noise sources in the oxide are implanted into the model and by using a Green's function approach, the spectral cross-correlation of the electrical potential is evaluated at each node in the device mesh in order to obtain a highly accurate physical description. In this paper, we evaluate the validity of the classical model. In view of this, we have compared simulation results to those of the classical formulation and to experimental data. A good agreement with measurements is obtained with the proposed model. The results show that the noise behavior in FDSOI MOSFETs is strongly related to the front and buried oxides defects, even if the channel is located at the front interface. In other words the classical formulation of the flat-band voltage PSD overestimate the front oxide trap density and no more holds true in SOI MOSFETs LFN characterization.

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基于格林函数法的SOI mosfet低频噪声建模

本文提出了超薄体FDSOI MOSFET器件中反转电荷功率谱密度的一种新的数值模型。与以往的经典模型不同，我们没有使用将氧化物电荷波动与平带电压波动联系起来的等效概念。氧化物中的局部噪声源被植入到模型中，并通过使用格林函数方法，在设备网格中的每个节点上评估电位的频谱相互关系，以获得高度精确的物理描述。在本文中，我们评估了经典模型的有效性。鉴于此，我们将模拟结果与经典公式和实验数据进行了比较。该模型与实测结果吻合较好。结果表明，FDSOI mosfet中的噪声行为与前端和埋藏氧化物缺陷密切相关，即使沟道位于前端界面。换句话说，平面带电压PSD的经典公式高估了前氧化物阱密度，并且不再适用于SOI mosfet的LFN表征。

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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2011 21st International Conference on Noise and Fluctuations

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