Large-signal model of 2DFETs :: compact modeling of terminal charges and intrinsic capacitances

Francisco Pasadas; Enrique G. Marin; Alejandro Toral-Lopez; Francisco G. Ruiz; Andres Godoy Medina; Saungeun Park; Deji Akinwande; David Jiménez Jiménez

doi:10.1038/s41699-019-0130-6

Large-signal model of 2DFETs : compact modeling of terminal charges and intrinsic capacitances

Francisco Pasadas, Enrique G. Marin, Alejandro Toral-Lopez, Francisco G. Ruiz, Andres Godoy Medina, Saungeun Park, Deji Akinwande, David Jiménez Jiménez

Research output: Contribution to journal › Article › Research › peer-review

21 Citations (Scopus)

Abstract

We present a physics-based circuit-compatible model for double-gated two-dimensional semiconductor-based field-effect transistors, which provides explicit expressions for the drain current, terminal charges, and intrinsic capacitances. The drain current model is based on the drift-diffusion mechanism for the carrier transport and considers Fermi-Dirac statistics coupled with an appropriate field-effect approach. The terminal charge and intrinsic capacitance models are calculated adopting a Ward-Dutton linear charge partition scheme that guarantees charge conservation. It has been implemented in Verilog-A to make it compatible with standard circuit simulators. In order to benchmark the proposed modeling framework we also present experimental DC and high-frequency measurements of a purposely fabricated monolayer MoS-FET showing excellent agreement between the model and the experiment and thus demonstrating the capabilities of the combined approach to predict the performance of 2DFETs.

Original language	English
Journal	npj 2D Materials and Applications
Volume	3
DOIs	https://doi.org/10.1038/s41699-019-0130-6
Publication status	Published - 2019

Keywords

Charge conservation
Circuit compatible models
Circuit simulators
Drain current models
High frequency measurements
Intrinsic capacitance
Large signal modeling
Two-dimensional semiconductors

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10.1038/s41699-019-0130-6

https://ddd.uab.cat/record/223438

Cite this

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title = "Large-signal model of 2DFETs :: compact modeling of terminal charges and intrinsic capacitances",

abstract = "We present a physics-based circuit-compatible model for double-gated two-dimensional semiconductor-based field-effect transistors, which provides explicit expressions for the drain current, terminal charges, and intrinsic capacitances. The drain current model is based on the drift-diffusion mechanism for the carrier transport and considers Fermi-Dirac statistics coupled with an appropriate field-effect approach. The terminal charge and intrinsic capacitance models are calculated adopting a Ward-Dutton linear charge partition scheme that guarantees charge conservation. It has been implemented in Verilog-A to make it compatible with standard circuit simulators. In order to benchmark the proposed modeling framework we also present experimental DC and high-frequency measurements of a purposely fabricated monolayer MoS-FET showing excellent agreement between the model and the experiment and thus demonstrating the capabilities of the combined approach to predict the performance of 2DFETs.",

keywords = "Charge conservation, Circuit compatible models, Circuit simulators, Drain current models, High frequency measurements, Intrinsic capacitance, Large signal modeling, Two-dimensional semiconductors",

author = "Francisco Pasadas and Marin, \{Enrique G.\} and Alejandro Toral-Lopez and Ruiz, \{Francisco G.\} and \{Godoy Medina\}, Andres and Saungeun Park and Deji Akinwande and \{Jim{\'e}nez Jim{\'e}nez\}, David",

year = "2019",

doi = "10.1038/s41699-019-0130-6",

language = "English",

volume = "3",

journal = "npj 2D Materials and Applications",

issn = "2397-7132",

publisher = "Nature Publishing Group",

}

TY - JOUR

T1 - Large-signal model of 2DFETs :

T2 - compact modeling of terminal charges and intrinsic capacitances

AU - Pasadas, Francisco

AU - Marin, Enrique G.

AU - Toral-Lopez, Alejandro

AU - Ruiz, Francisco G.

AU - Godoy Medina, Andres

AU - Park, Saungeun

AU - Akinwande, Deji

AU - Jiménez Jiménez, David

PY - 2019

Y1 - 2019

N2 - We present a physics-based circuit-compatible model for double-gated two-dimensional semiconductor-based field-effect transistors, which provides explicit expressions for the drain current, terminal charges, and intrinsic capacitances. The drain current model is based on the drift-diffusion mechanism for the carrier transport and considers Fermi-Dirac statistics coupled with an appropriate field-effect approach. The terminal charge and intrinsic capacitance models are calculated adopting a Ward-Dutton linear charge partition scheme that guarantees charge conservation. It has been implemented in Verilog-A to make it compatible with standard circuit simulators. In order to benchmark the proposed modeling framework we also present experimental DC and high-frequency measurements of a purposely fabricated monolayer MoS-FET showing excellent agreement between the model and the experiment and thus demonstrating the capabilities of the combined approach to predict the performance of 2DFETs.

AB - We present a physics-based circuit-compatible model for double-gated two-dimensional semiconductor-based field-effect transistors, which provides explicit expressions for the drain current, terminal charges, and intrinsic capacitances. The drain current model is based on the drift-diffusion mechanism for the carrier transport and considers Fermi-Dirac statistics coupled with an appropriate field-effect approach. The terminal charge and intrinsic capacitance models are calculated adopting a Ward-Dutton linear charge partition scheme that guarantees charge conservation. It has been implemented in Verilog-A to make it compatible with standard circuit simulators. In order to benchmark the proposed modeling framework we also present experimental DC and high-frequency measurements of a purposely fabricated monolayer MoS-FET showing excellent agreement between the model and the experiment and thus demonstrating the capabilities of the combined approach to predict the performance of 2DFETs.

KW - Charge conservation

KW - Circuit compatible models

KW - Circuit simulators

KW - Drain current models

KW - High frequency measurements

KW - Intrinsic capacitance

KW - Large signal modeling

KW - Two-dimensional semiconductors

UR - https://www.scopus.com/pages/publications/85076011010

U2 - 10.1038/s41699-019-0130-6

DO - 10.1038/s41699-019-0130-6

M3 - Article

SN - 2397-7132

VL - 3

JO - npj 2D Materials and Applications

JF - npj 2D Materials and Applications

ER -

Large-signal model of 2DFETs : compact modeling of terminal charges and intrinsic capacitances

Abstract

Keywords

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