Issue 12, 2023

A steep-switching impact ionization-based threshold switching field-effect transistor

Abstract

A steep switching device with a low subthreshold swing (SS) that overcomes the fundamental Boltzmann limit (kT/q) is required to efficiently process a continuously increasing amount of data. Recently, two-dimensional material-based impact ionization transistors with various structures have been reported with the advantages of a low critical electric field and a unique quantum confinement effect. However, most of them cannot retain steep switching at room temperature, and device performance degradation issues caused by impact ionization-induced hot carriers have not been structurally addressed. In this study, we presented an impact-ionization-based threshold switching field-effect transistor (I2S-FET) fabricated with a serial connection of a MoS2 FET and WSe2 impact ionization-based threshold switch (I2S). We obtained repetitive operation with low SS (32.8 mV dec−1) at room temperature, along with low dielectric injection efficiency (10−6), through a structural design with separation of the conducting region, which determines on-state carrier transport, and the steep-switching region where the transition from off- to on-state occurs via impact ionization. Furthermore, compared to previously reported threshold-switching devices, our device demonstrated hysteresis-free switching characteristics. This study provides a promising approach for developing next-generation energy-efficient electronic devices and ultralow-power applications.

Graphical abstract: A steep-switching impact ionization-based threshold switching field-effect transistor

Supplementary files

Article information

Article type
Paper
Submitted
23 Nov 2022
Accepted
19 Feb 2023
First published
20 Feb 2023

Nanoscale, 2023,15, 5771-5777

A steep-switching impact ionization-based threshold switching field-effect transistor

C. Kang, H. Choi, H. Son, T. Kang, S. Lee and S. Lee, Nanoscale, 2023, 15, 5771 DOI: 10.1039/D2NR06547A

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