Nano Research | 2021
Device performance limit of monolayer SnSe2 MOSFET
Abstract
Two-dimensional (2D) semiconductors are attractive channels to shrink the scale of field-effect transistors (FETs), and among which the anisotropic one is more advantageous for a higher on-state current (Ion). Monolayer (ML) SnSe2, as an abundant, economic, nontoxic, and stable two-dimensional material, possesses an anisotropic electronic nature. Herein, we study the device performances of the ML SnSe2 metal-oxide-semiconductor FETs (MOSFETs) and deduce their performance limit to an ultrashort gate length (Lg) and ultralow supply voltage (Vdd) by using the ab initio quantum transport simulation. An ultrahigh Ion of 5,660 and 3,145 µA/µm is acquired for the n-type 10-nm-Lg ML SnSe2 MOSFET at Vdd = 0.7 V for high-performance (HP) and low-power (LP) applications, respectively. Specifically, until Lg scales down to 2 and 3 nm, the MOSFETs (at Vdd = 0.65 V) surpass Ion, intrinsic delay time (τ), and power-delay product (PDP) of the International Roadmap for Device and Systems (IRDS, 2020 version) for HP and LP devices for the year 2028. Moreover, the 5-nm-Lg ML SnSe2 MOSFET (at Vdd = 0.4 V) fulfills the IRDS HP device and the 7-nm-Lg MOSFET (at Vdd = 0.55 V) fulfills the IRDS LP device for the year 2034.