Device-to-circuit modeling approach to Metal – Insulator – 2D material FETs targeting the design of linear RF applications

2019 International Conference on Simulation of Semiconductor Processes and Devices (SISPAD) Pub Date : 2019-09-01 DOI:10.1109/SISPAD.2019.8870562

A. Toral-Lopez, F. Pasadas, E. G. Marín, A. Medina-Rull, F. Ruiz, D. Jiménez, A. Godoy

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引用次数: 2

Abstract

We present a physics-based device-to-circuit modeling approach to metal – insulator – 2D material based field-effect transistors (2DFETs). Starting from numerical simulations based on the self-consistent solution of the 2D Poisson and 1D Drift-Diffusion equations, we obtain the electrostatics and current-voltage characteristics of such devices. Then, assuming small-signal operation, a charge-based equivalent circuit is fed with the small-signal parameters computed from the numerical results and then it is implemented in a standard circuit simulator. This framework enables the design and assessment of linear radio-frequency applications based on novel and emergent 2DFETs. The approach has been applied to an experimental MoS2 transistor by benchmarking the transfer characteristics and then predicting the expected performance of such device as a common-source power amplifier, for instance a power gain of 8.6 dB at 2.45 GHz.

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针对线性射频应用设计的金属-绝缘体-二维材料场效应管的器件到电路建模方法

我们提出了一种基于物理的器件到电路建模方法，用于金属绝缘体二维材料场效应晶体管(2dfet)。基于二维泊松方程和一维漂移-扩散方程的自一致解，从数值模拟出发，得到了该类器件的静电特性和电流-电压特性。然后，假设小信号工作，将数值计算得到的小信号参数馈送到基于电荷的等效电路中，然后在标准电路模拟器中实现。该框架能够设计和评估基于新型和新兴2dfet的线性射频应用。该方法已应用于实验MoS2晶体管，通过对传输特性进行基准测试，然后预测该器件作为共源功率放大器的预期性能，例如在2.45 GHz时的功率增益为8.6 dB。

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2019 International Conference on Simulation of Semiconductor Processes and Devices (SISPAD)

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