Tunnel FETs: Surpassing the Energy Efficiency of Conventional MOSFETs (Sandia Labs)

A new technical paper titled “Next-generation tunnel FETs: exploring material perspectives and areal tunneling configurations” was published by researchers at Sandia National Laboratories.

Abstract

“The end of Dennard scaling, which facilitated proportional increases in computing power without added energy costs until the mid-2000s, has underscored the urgent need for innovative semiconductor devices that can enhance energy efficiency. Tunnel field-effect transistors (TFETs) have emerged as promising candidates to surpass the energy efficiency of conventional metal oxide semiconductor field-effect transistors (MOSFETs). Unlike MOSFETs, which rely on thermionic emission to overcome the source-channel potential barrier, TFETs operate through quantum tunneling, potentially enabling sub-60 mV dec^-1 subthreshold swing (SS) for low-voltage operation. However, lateral TFETs have faced challenges in achieving adequate on-state current (I_ON) and a broad SS operation window, limiting their practical utility. This review article advocates for areal TFETs, which utilize face-to-face tunnel junctions that ideally offer step-function current turn-on characteristics and allow I_ON to scale with device area rather than width. We highlight recent advancements in integrating 2D materials into tunneling structures, which could facilitate efficient band-to-band tunneling through atomically thin layers, while addressing challenges of gate field screening. We then discuss the nearer-term prospects of epitaxial areal TFETs comprising III–V compound semiconductors and group-IV semiconductors based on recent experimental progress. The review examines both quantum mechanical and semiclassical modeling approaches for TFETs, including techniques to reduce the computational complexity. The article delves into ongoing challenges in material synthesis, interface engineering, device fabrication, and integration pathways, concluding with recommendations for future research directions to overcome the fundamental power density limitations of conventional transistor technology.”

Find the technical paper here. November 2025.

Allemang, Christopher Richard, Evan Michael Anderson, Xujiao Gao, C. Arose, J. P. Mendez, Thomas Alan Weingartner, D. M. Campbell, A. J. Muhowski, Tzu-Ming Lu, and Shashank Misra. “Next-generation tunnel FETs: exploring material perspectives and areal tunneling configurations.” Materials for Quantum Technology 5, no. 4 (2025): 042002. Creative commons license.