Self-organization and the physics of glassy networks

P. Boolchand; G. Lucovsky; J. C. Phillips; Michael Thorpe

doi:10.1080/14786430500256425

Self-organization and the physics of glassy networks

P. Boolchand, G. Lucovsky, J. C. Phillips, Michael Thorpe

Research output: Contribution to journal › Article › peer-review

155 Scopus citations

Abstract

Network glasses are the physical prototype for many self-organized systems, ranging from proteins to computer science. Conventional theories of gases, liquids and crystals do not account for the strongly material-selective character of the glass-forming tendency, the phase diagrams of glasses or their optimizable properties. A new topological theory, only 25 years old, has succeeded where conventional theories have failed. It shows that (probably all slowly quenched) glasses, including network glasses, are the result of the combined effects of a few simple mechanisms. These glass-forming mechanisms are topological in nature and have already been identified for several important glasses, including chalcogenide alloys, silicates (window glass and computer chips) and proteins.

Original language	English (US)
Pages (from-to)	3823-3838
Number of pages	16
Journal	Philosophical Magazine
Volume	85
Issue number	32
DOIs	https://doi.org/10.1080/14786430500256425
State	Published - Nov 11 2005

ASJC Scopus subject areas

Condensed Matter Physics

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10.1080/14786430500256425

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AB - Network glasses are the physical prototype for many self-organized systems, ranging from proteins to computer science. Conventional theories of gases, liquids and crystals do not account for the strongly material-selective character of the glass-forming tendency, the phase diagrams of glasses or their optimizable properties. A new topological theory, only 25 years old, has succeeded where conventional theories have failed. It shows that (probably all slowly quenched) glasses, including network glasses, are the result of the combined effects of a few simple mechanisms. These glass-forming mechanisms are topological in nature and have already been identified for several important glasses, including chalcogenide alloys, silicates (window glass and computer chips) and proteins.

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Self-organization and the physics of glassy networks

Abstract

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