Analysis and Design of FeFET Synapse With Stacked-Nanosheet Architecture Considering Cycle-to-Cycle Variations for Neuromorphic Applications

IF 1.8 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY IEEE Open Journal of Nanotechnology Pub Date : 2024-03-10 DOI:10.1109/OJNANO.2024.3399559

Heng Li Lin;Pin Su

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Abstract

Using extensive Monte-Carlo simulations with a nucleation-limited-switching (NLS) ferroelectric model and considering cycle-to-cycle variations, this paper constructs and analyzes the intrinsic conductance (G _DS ) response of stacked-nanosheet FeFET synapses with emphasis on the challenging identical-pulse stimulation. Our study indicates that the interlayer oxide thickness of the FeFET and the saturation polarization of the ferroelectric are crucial to the linearity and symmetry of the intrinsic G _DS response. With the stacked-nanosheet architecture, the maximum-to-minimum conductance ratio in the G _DS response can be boosted by increasing the number of channel tiers without footprint penalty. For a stacked-nanosheet FeFET synapse with an area ratio effect, the G _DS response can be further engineered by varying the tier number. In addition, the immunity to cycle-to-cycle variations and the noise margin for each state in the G _DS response can also be improved by increasing the number of tiers. Our study may provide insights for future FeFET synapse design for analog computing.

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考虑到神经形态应用中周期间变化的叠层纳米片架构 FeFET 突触的分析与设计

本文利用成核限制开关（NLS）铁电模型进行了大量蒙特卡洛模拟，并考虑了周期之间的变化，构建并分析了叠层纳米片 FeFET 突触的本征电导（GDS）响应，重点研究了具有挑战性的相同脉冲刺激。我们的研究表明，FeFET 的层间氧化物厚度和铁电体的饱和极化对本征 GDS 响应的线性和对称性至关重要。采用叠层纳米片结构，可以通过增加沟道层数来提高 GDS 响应中的最大与最小电导比，而不会对基底面造成影响。对于具有面积比效应的叠层纳米片 FeFET 突触，可以通过改变层数进一步设计 GDS 响应。此外，GDS 响应中每个状态对周期变化的抗扰度和噪声裕度也可以通过增加层数来改善。我们的研究可为未来模拟计算的 FeFET 突触设计提供启示。

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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