Mechanical memories in solids, from disorder to design

Joseph D. Paulsen, Nathan C. Keim
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Abstract

Solids are rigid, which means that when left undisturbed, their structures are nearly static. It follows that these structures depend on history -- but it is surprising that they hold readable memories of past events. Here we review the research that has recently flourished around mechanical memory formation, beginning with amorphous solids' various memories of deformation and mesoscopic models based on particle rearrangements. We describe how these concepts apply to a much wider range of solids and glassy matter -- and how they are a bridge to memory and physical computing in mechanical metamaterials. An understanding of memory in all these solids can potentially be the basis for designing or training functionality into materials. Just as important is memory's value for understanding matter whenever it is complex, frustrated, and out of equilibrium.
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固体中的机械记忆,从无序到设计
固体是刚性的,这意味着在不受干扰的情况下,它们的结构几乎是静态的。因此,这些结构依赖于历史--但令人惊讶的是,它们对过去的事件拥有可读的记忆。在此,我们回顾了最近围绕机械记忆形成而蓬勃发展的研究,首先是无定形固体的各种变形记忆和基于粒子重排的介观模型。我们将介绍这些概念如何适用于更广泛的固体和玻璃物质,以及它们如何成为机械超材料中记忆和物理计算的桥梁。了解所有这些固体的记忆,有可能成为设计或训练材料功能的基础。同样重要的是,只要物质是复杂的、受挫的和非平衡的,记忆对于理解物质的价值就不言而喻。
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