Abstract
In this article, we present a channel thickness dependent analytical model for MoS2 symmetric double-gate FETs including negative capacitance (NC) effect. In the model development, first thickness dependent model of the baseline 2D FET is developed, and later NC effect is included in the model using the Landau-Khalatnikov (L-K) relation. To validate baseline model behavior, density functional theory (DFT) calculations are taken into account to obtain numerical data for the $K$ and $\Lambda $ valley dependent effective masses and differences in the energy levels of N-layer (N = 1, 2, 3, 4, and 5) MoS2. The calculated layer dependent parameters using DFT theory are further used in a drift-diffusion simulator to obtain electric characteristics of the baseline 2D FET for model validation. The model shows excellent match for drain current and total gate capacitance of baseline FET and NCFET against the numerical simulation.
Highlights
To obtain performance improvement in a field-effecttransistor (FET) characteristics with scaling, many techniques are being explored and replacing silicon in the channel region with an alternative material is one of the attractive and viable option
In addition to geometrical scaling, application of negative capacitance has been demonstrated in conventional silicon and TMD channel based devices to achieve power supply scaling [11]–[14]
Application of the TMD based FETs has already been demonstrated in an inverter, a NAND gate, a static random access memory (SRAM), and a five-stage ring oscillator based on a direct-coupled transistor logic technology [18]
Summary
To obtain performance improvement in a field-effecttransistor (FET) characteristics with scaling, many techniques are being explored and replacing silicon in the channel region with an alternative material is one of the attractive and viable option. NANDAN et al.: COMPACT MODELING OF MULTI-LAYERED MOS2 FETs INCLUDING NEGATIVE CAPACITANCE EFFECT We present a surface potential based compact model for drain current of multilayer MoS2 symmetric double-gate structure including NC effect extending our previous IEEE EDTM-2019 work [33].
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