Modulation of the Conductive Filament Growth During the Electroforming Process in Metal Oxide-Based RRAM

Kena Zhang, Yao Ren
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Abstract

Metal oxide-based Resistive Random-Access Memories (RRAM) exhibit multiple intermediate resistive states, due to the formation/rupture of a conductive filament (CF) inside a switching layer. While there have been extensive studies on the resistive switching behavior caused by a pre-existing CF, the initial stage of the formation and growth of a CF, i.e., the electroforming process has been less understood.  In this work, we developed a physical model to fundamentally understand the formation and growth behavior of a CF in a metal oxide layer constrained by the top/bottom electrodes. It is revealed that the CF formation is assisted by the supply of oxygen vacancies at the anode and the oxygen vacancies transport in the oxide layer. The effects of the external conditions (the oxygen exchange rate j 0 and the applied voltage) and the physical properties of the oxides (the electrical σ and thermal conductivity k th ) on the CF morphology evolution, current density evolution, and local temperature and electrical potential distribution have been systematically explored. It is found that larger oxygen vacancy exchange rate and relatively small voltage sweep rate result in a more uniform CF. Furthermore, by choosing oxides with lower Lorenz number (ratio of k th and σ ), CF with more homogeneous morphology can be realized.  This work provides a fundamental understanding of the kinetic behaviors of the CF formation and growth during the electroforming process, and could potentially guide the oxide and electrode materials selection, synthesis and working conditions for switching to achieve improved RRAM stability and functionality.
金属氧化物基RRAM电铸过程中导电丝生长的调制
基于金属氧化物的电阻性随机存取存储器(RRAM)由于开关层内导电丝(CF)的形成/破裂而表现出多种中间电阻状态。虽然对预先存在的CF引起的电阻开关行为进行了广泛的研究,但对CF形成和生长的初始阶段,即电铸过程的了解较少。在这项工作中,我们开发了一个物理模型,从根本上了解CF在受上下电极约束的金属氧化物层中的形成和生长行为。结果表明,阳极氧空位的供给和氧化层中氧空位的输运有助于CF的形成。系统地探讨了外部条件(氧交换率j 0和外加电压)和氧化物的物理性质(电学σ和导热系数k th)对CF形貌演变、电流密度演变、局部温度和电势分布的影响。结果表明,较大的氧空位交换率和较小的电压扫频率可以得到更均匀的CF,选择较低洛伦兹数(k与σ之比)的氧化物可以得到形貌更均匀的CF。这项工作提供了对电铸过程中CF形成和生长的动力学行为的基本理解,并可能指导氧化物和电极材料的选择、合成和工作条件的切换,以实现提高RRAM的稳定性和功能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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