Mechanical Memories in Solids, from Disorder to Design

Joseph D. Paulsen; Nathan C. Keim

doi:10.1146/annurev-conmatphys-032822-035544

Mechanical Memories in Solids, from Disorder to Design

Joseph D. Paulsen, Nathan C. Keim

Physics

Research output: Contribution to journal › Review article › peer-review

9 Scopus citations

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.

Original language	English (US)
Pages (from-to)	61-81
Number of pages	21
Journal	Annual Review of Condensed Matter Physics
Volume	16
Issue number	1
DOIs	https://doi.org/10.1146/annurev-conmatphys-032822-035544
State	Published - Mar 10 2025

All Science Journal Classification (ASJC) codes

General Materials Science
Condensed Matter Physics

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10.1146/annurev-conmatphys-032822-035544

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title = "Mechanical Memories in Solids, from Disorder to Design",

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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AU - Keim, Nathan C.

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N2 - 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.

AB - 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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Mechanical Memories in Solids, from Disorder to Design

Abstract

All Science Journal Classification (ASJC) codes

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