Winkler Robert, Zintler Alexander, Petzold Stefan, Piros Eszter, Kaiser Nico, Vogel Tobias, Nasiou Déspina, McKenna Keith P, Molina-Luna Leopoldo, Alff Lambert
Advanced Thin Film Technology Division, Institute of Materials Science, Technical University of Darmstadt, Alarich-Weiss-Straße 2, 64287, Darmstadt, Germany.
Advanced Electron Microscopy Division, Institute of Materials Science, Technical University of Darmstadt, Alarich-Weiss-Straße 2, 64287, Darmstadt, Germany.
Adv Sci (Weinh). 2022 Nov;9(33):e2201806. doi: 10.1002/advs.202201806. Epub 2022 Sep 8.
Resistive random-access memories are promising candidates for novel computer architectures such as in-memory computing, multilevel data storage, and neuromorphics. Their working principle is based on electrically stimulated materials changes that allow access to two (digital), multiple (multilevel), or quasi-continuous (analog) resistive states. However, the stochastic nature of forming and switching the conductive pathway involves complex atomistic defect configurations resulting in considerable variability. This paper reveals that the intricate interplay of 0D and 2D defects can be engineered to achieve reproducible and controlled low-voltage formation of conducting filaments. The author find that the orientation of grain boundaries in polycrystalline HfO is directly related to the required forming voltage of the conducting filaments, unravelling a neglected origin of variability. Based on the realistic atomic structure of grain boundaries obtained from ultra-high resolution imaging combined with first-principles calculations including local strain, this paper shows how oxygen vacancy segregation energies and the associated electronic states in the vicinity of the Fermi level govern the formation of conductive pathways in memristive devices. These findings are applicable to non-amorphous valence change filamentary type memristive device. The results demonstrate that a fundamental atomistic understanding of defect chemistry is pivotal to design memristors as key element of future electronics.
电阻式随机存取存储器是诸如内存计算、多级数据存储和神经形态计算等新型计算机架构的有前途的候选者。它们的工作原理基于电刺激引起的材料变化,这种变化允许访问两种(数字)、多种(多级)或准连续(模拟)电阻状态。然而,形成和切换导电通路的随机性涉及复杂的原子缺陷构型,导致相当大的变异性。本文揭示了可以通过设计0D和2D缺陷的复杂相互作用,来实现导电细丝的可重复和可控的低电压形成。作者发现,多晶HfO中晶界的取向与导电细丝所需的形成电压直接相关,揭示了一个被忽视的变异性来源。基于从超高分辨率成像获得的晶界的真实原子结构,结合包括局部应变的第一性原理计算,本文展示了氧空位偏析能以及费米能级附近的相关电子态如何控制忆阻器件中导电通路的形成。这些发现适用于非非晶价变丝状忆阻器件。结果表明,对缺陷化学的基本原子理解对于将忆阻器设计为未来电子学的关键元件至关重要。
