数据保留
不稳定性
材料科学
可靠性(半导体)
动力学蒙特卡罗方法
限制
电阻式触摸屏
蒙特卡罗方法
期限(时间)
噪音(视频)
电阻随机存取存储器
氧化物
计算机科学
纳米技术
统计物理学
可靠性工程
机械
光电子学
电气工程
物理
工程类
机械工程
人工智能
电压
功率(物理)
冶金
图像(数学)
统计
数学
量子力学
计算机视觉
作者
Nils Kopperberg,Stefan Wiefels,Sergej Liberda,Rainer Waser,Stephan Menzel
标识
DOI:10.1021/acsami.1c14667
摘要
Major challenges concerning the reliability of resistive switching random access memories based on the valence change mechanism (VCM) are short-term instability and long-term retention failure of the programmed resistance state, particularly in the high resistive state. On the one hand, read noise limits the reliability of VCMs via comparatively small current jumps especially when looking at the statistics of millions of cells that are needed for industrial applications. Additionally, shaping algorithms aiming for an enlargement of the read window are observed to have no lasting effect. On the other hand, long-term retention failures limiting the lifetime of the programmed resistance states need to be overcome. The physical origin of these phenomena is still under debate and needs to be understood much better. In this work, we present a three-dimensional kinetic Monte Carlo simulation model where we implemented diffusion-limiting domains to the oxide layer of the VCM cell. We demonstrate that our model can explain both instability and retention failure consistently by the same physical processes. Further, we find that the random diffusion of oxygen vacancies plays an important role regarding the reliability of VCMs and can explain instability phenomena as the shaping failure as well as the long-term retention failure in our model. Additionally, the results of the simulations are compared with experimental data of read noise and retention investigations on ZrO2-based VCM devices.
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