Stochasticity-by-Design in Memristive Materials for Probabilistic Computing and Hardware Security: Entropy Sources, Control Knobs, and Benchmarks

概率逻辑 随机性 计算机科学 记忆电阻器 工具箱 电阻随机存取存储器 熵(时间箭头) 分布式计算 钥匙(锁) 计算机工程 信息物理系统 神经形态工程学 硬件安全模块 理论计算机科学 高效能源利用 物理系统 可靠性(半导体) 巨量平行 人工神经网络 随机计算 随机数生成 可靠性 软件 复杂系统
作者
Daiyang Jiang,Changtian Cao,Junming Zhang,Ouwen Zhang,Chuqian Zhu,Jiyang Xu,Qinyan Zhang,Wenhao Li,Yumin Da,Xiangshui Miao,Zuhao Shi,Huajun Sun
出处
期刊:ACS applied electronic materials [American Chemical Society]
卷期号:8 (4): 1492-1519
标识
DOI:10.1021/acsaelm.5c02703
摘要

The computing paradigm is shifting from traditional deterministic models to probabilistic models inspired by the brain. This shift aims to address complex problems in fields such as artificial intelligence, optimization, and security with greater energy efficiency. However, achieving efficient sources of randomness at the hardware level remains a significant challenge. Memristors exhibit intrinsic nanoscale resistive switching randomness, offering a physical foundation for probabilistic computing and hardware security. Traditionally, this variability has been viewed as a reliability issue in memory applications; however, the emerging concept of “stochasticity-by-design” is transforming it into an exploitable functional property. This review provides a comprehensive, materials-focused perspective on this rapidly evolving field. We analyze the physical origins of randomness, namely, “entropy sources”, in different memristive material systems, covering conductive bridges (ECMs), valence state changes (VCMs), Mott transitions, and proton transport mechanisms. Building on this foundation, we systematically outline a toolbox of “control knobs” for precisely tuning these random properties, spanning material, device, and operational levels. We then establish clear performance benchmarks for two key applications: probabilistic computing and hardware security, directly linking the device’s physical properties to application requirements. Finally, we explore the challenges of moving from single devices to large-scale system integration, discuss the trade-off between randomness and determinism, and highlight recent advances in multifunctional devices with tunable randomness. Here, we provide researchers with a unified framework from fundamental physics to system applications, offering a roadmap for optimizing random memristive materials for next-generation security hardware.
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