硫族相变存储电池的电学仿真模型

Records of the 2003 International Workshop on Memory Technology, Design and Testing Pub Date : 2003-07-28 DOI:10.1109/MTDT.2003.1222366

D. Salamon, B. Cockburn

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引用次数: 12

摘要

一些公司正在研究硫化物玻璃作为可扩展和可嵌入的非易失性相变存储技术的基础。一个相是高电阻非晶相，它是通过用欧姆加热熔化小体积的玻璃，然后淬火而得到的。第二相是低电阻结晶相，通过将玻璃加热到刚好低于熔点以促进再结晶而获得。本文描述了这种细胞的两个模型。第一种是一个非常简单的单元素集总模型，它表现出正确的相变行为，但对加热电流脉冲的灵敏度不现实。第二，多元素模型能够更真实地表示电池的加热和冷却行为，并且似乎是更合适的电模拟模型的基础。

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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An electrical simulation model for the chalcogenide phase-change memory cell

Chalcogenide glass is being investigated by several companies as the basis for a scalable and embeddable nonvolatile phase-change memory technology. One phase is a high-resistance amorphous phase that is obtained by melting a small volume of glass using ohmic heating, and then quenching it. The second phase is a low-resistance crystalline phase that is obtained by heating the glass to just below the melting point to promote recrystallization. This paper describes two models for such a cell. The first is a very simple single-element, lumped model that exhibits correct phase transition behavior, but is unrealistic in its sensitivity to the heating current pulses. The second, multiple-element model is able to more realistically represent cell heating and cooling behavior, and appears to be the more suitable basis for an electrical simulation model.

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Records of the 2003 International Workshop on Memory Technology, Design and Testing

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