Publication

Fully coupled electron-phonon transport in two-dimensional-material-based devices using efficient FFT-based self-energy calculations

Journal Contribution - Journal Article

Abstract:Self-heating can significantly degrade the performance in silicon nanoscale devices. In this work, the impact of self-heating is investigated in nanosheet transistors made of two-dimensional materials using ab-initio techniques. A new algorithm was developed to allow for efficient self-energy computations, achieving a similar to 500 times speedup. It is found that for the simple case of free-standing transition-metal dicalchogenides without explicit metal leads, electron-phonon scattering with room-temperature phonons dominates the device performance. For MoS2, the effect of self-heating is negligible in comparison. For WS2 and especially for WSe2, self-heating effects demonstrate a further degradation of the ON-state current.

Published in: COMPUTER PHYSICS COMMUNICATIONS

ISSN: 0010-4655

Issue: February

Volume: 307

Publication year:2025

Keywords:Computer science/information technology, Mathematical & theoretical physics

DOI: https://doi.org/10.1016/j.cpc.2024.109430
Institutional Repository URL: https://imec-publications.be/handle/20.500.12860/44868.2

Accessibility:Open

See also: Fully coupled electron-phonon transport in two-dimensional-material-based devices using efficient FFT-based self-energy calculations

Publication

Fully coupled electron-phonon transport in two-dimensional-material-based devices using efficient FFT-based self-energy calculations

Journal Contribution - Journal Article

SDG-label by Aurora

Authors/publisher

Research units