Boosting Stochasticity in Ovonic Threshold Switches Through Cryogenic First Firing for Fast and Reliable Entropy Generation

Boosting Stochasticity in Ovonic Threshold Switches Through Cryogenic First Firing for Fast and Reliable Entropy Generation

Abstract As encryption demands at the edges grow, volatile switching devices have emerged as promising candidates for entropy sources because of their inherent stochastic properties, offering fast, energy‐efficient operation and a minimal footprint. Although most studies have focused on exploiting i...

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Main Authors: Dongmin Kim, Jangseop Lee, Yoori Seo, Ohhyuk Kwon, Pendar Azaripour Masouleh, Jisung Lee, Joonhyun Kwon, Chul‐Heung Kim, Hyunsang Hwang
Format: Article
Language:English
Published: Wiley-VCH 2025-06-01
Series:Advanced Electronic Materials
Subjects:
cryptography
hardware security
ovonic threshold switching
stochastic
true random‐number generator
Online Access:https://doi.org/10.1002/aelm.202400881
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Summary:Abstract As encryption demands at the edges grow, volatile switching devices have emerged as promising candidates for entropy sources because of their inherent stochastic properties, offering fast, energy‐efficient operation and a minimal footprint. Although most studies have focused on exploiting inherent stochasticity, efforts to analyze and optimize these devices to enhance their randomness remain scarce. In this study, the stochastic switching characteristics of Ovonic Threshold Switch (OTS) devices by controlling the first firing temperatures to amplify their inherent stochasticity are explored. It is demonstrated that firing at cryogenic temperatures (77 K) induces field‐dominant firing and a considerable increase in traps within the device. These additional traps lead to a substantial enhancement in switching variability, with the switching time fluctuation increasing up to four times compared to the first firing temperature of 298 K. Furthermore, a reference‐free entropy‐harvesting method is proposed that ensures robust and stable operation even under cycling degradation. Based on this approach, the OTS devices that undergo first firing at cryogenic temperatures achieve stable entropy generation at speeds exceeding 20 Mbit s−1. This study demonstrates the potential of optimizing OTS devices to satisfy the increasing demand for fast and energy‐efficient entropy sources in advanced cryptographic systems.
ISSN:2199-160X

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