Two-dimensional Cold Electron Transport for Steep-slope Transistors
Abstract
Room-temperature Fermi-Dirac electron thermal excitation in conventional three-dimensional (3D) or two-dimensional (2D) semiconductors generates hot electrons with a relatively long thermal tail in energy distribution. These hot electrons set a fundamental obstacle known as the "Boltzmann tyranny" that limits the subthreshold swing (SS) and therefore the minimum power consumption of 3D and 2D field-effect transistors (FETs). Here, we investigated a novel graphene (Gr)-enabled cold electron injection where the Gr acts as the Dirac source to provide the cold electrons with a localized electron density distribution and a short thermal tail at room temperature. These cold electrons correspond to an electronic cooling effect with the effective electron temperature of ~145 K in the monolayer MoS2, which enable the transport factor lowering and thus the steep-slope switching (across for 3 decades with a minimum SS of 29 mV/decade at room temperature) for a monolayer MoS2 FET. Especially, a record-high sub-60-mV/decade current density (over 1 {\mu}A/{\mu}m) can be achieved compared to conventional steep-slope technologies such as tunneling FETs or negative capacitance FETs using 2D or 3D channel materials. Our work demonstrates the great potential of 2D Dirac-source cold electron transistor as an innovative steep-slope transistor concept, and provides new opportunities for 2D materials toward future energy-efficient nanoelectronics.
Cite
@article{arxiv.2012.13970,
title = {Two-dimensional Cold Electron Transport for Steep-slope Transistors},
author = {Maomao Liu and Hemendra Nath Jaiswal and Simran Shahi and Sichen Wei and Yu Fu and Chaoran Chang and Anindita Chakravarty and Xiaochi Liu and Cheng Yang and Yanpeng Liu and Young Hee Lee and Fei Yao and Huamin Li},
journal= {arXiv preprint arXiv:2012.13970},
year = {2020}
}
Comments
currently under review