Enhancing Ga─Sb Bonds by GaSb Co-Doping Ge2Sb2Te5 for High Speed and Thermal Stability Phase Change Memory

IF 5.3 2区材料科学 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY

Advanced Electronic Materials Pub Date : 2025-04-22 DOI:10.1002/aelm.202500032

Ke Gao, Ruizhe Zhao, Xin Li, Jingwei Cai, Hao Tong, Xiangshui Miao

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Abstract

Chalcogenide phase change memory, a next-generation non-volatile memory technology, holds significant promise in neuromorphic computing, leading to an urgent demand for high-performance phase change materials. However, in the realm of phase change materials, there appears to be an inherent contradiction between enhancing crystallization speed and bolstering amorphous stability. In this work, the formation of Ga─Ge bonds associated with Ga single doping are effectively addressed through the deliberate incorporation of GaSb co-doping. This strategic approach to bonding variety has significantly improved operational speed to a remarkable 8 ns, the crystallization temperature is elevated to 196 °C, and multilevel phase change performance is retained. First-principles calculations and material characterization is conducted to elucidate the underlying mechanisms responsible for the observed enhancements in both thermal stability and operation speed. This investigation provides valuable insights for optimizing the performance of phase change materials and addresses the pressing challenge of integrating phase change materials into a neuromorphic computing system.

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通过 GaSb 共掺杂 Ge2Sb2Te5 来增强 Ga─Sb 键，从而实现高速度和热稳定性相变存储器

钙钛矿相变存储器是下一代非易失性存储器技术，在神经形态计算领域大有可为，因此对高性能相变材料的需求十分迫切。然而，在相变材料领域，提高结晶速度与增强非晶稳定性之间似乎存在内在矛盾。在这项工作中，通过有意识地加入 GaSb 共掺杂，有效地解决了与 Ga 单掺杂相关的 Ga─Ge 键的形成问题。这种策略性的键合方法将运行速度显著提高到 8 ns，结晶温度升高到 196 °C，并保留了多级相变性能。通过第一性原理计算和材料表征，阐明了热稳定性和运行速度提高的内在机理。这项研究为优化相变材料的性能提供了宝贵的见解，并解决了将相变材料集成到神经形态计算系统中的迫切挑战。

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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来源期刊

Advanced Electronic Materials NANOSCIENCE & NANOTECHNOLOGYMATERIALS SCIE-MATERIALS SCIENCE, MULTIDISCIPLINARY

CiteScore

11.00

自引率

3.20%

发文量

433

期刊介绍： Advanced Electronic Materials is an interdisciplinary forum for peer-reviewed, high-quality, high-impact research in the fields of materials science, physics, and engineering of electronic and magnetic materials. It includes research on physics and physical properties of electronic and magnetic materials, spintronics, electronics, device physics and engineering, micro- and nano-electromechanical systems, and organic electronics, in addition to fundamental research.