Bead Pack
Category=PHV
Concentrated Emulsions
condensed matter theory
confined systems dynamics
Correlation Function
Dense
Density Fluctuations
Dynamic Heterogeneity
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Force Chains
Fragile Glass Formers
Free Volume
glass transition supercooled liquids
Granular Media
Hard Sphere
Hard Sphere Colloids
Hard Sphere System
mechanical properties materials
Mode Coupling Theory
Nonzero Fraction
Packing Fraction
PACS
particle arrest phenomena
Plateau Borders
Power Law Decay
Shear Rate
soft condensed matter physics
Spin Glass Models
Spin Glasses
structural relaxation
Supercooled Liquid
Vogel Fulcher Law
Volume Fraction
Product details
- ISBN 9780748408795
- Weight: 1260g
- Dimensions: 174 x 246mm
- Publication Date: 22 Feb 2001
- Publisher: Taylor & Francis Ltd
- Publication City/Country: GB
- Product Form: Hardback
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The subject of jamming and rheology is a broad and interdisciplinary one that is generating increasing interest. This book deals with one of the oldest unsolved problems in condensed matter physics - that of the nature of glass transition in supercooled liquids.
Jamming and Rheology is a collection of reprinted articles from several fields, ranging from structural glasses to foams and granular materials.
Glassy relaxation and constrained dynamics (jamming) occur at all scales, from microscopic to macroscopic - in the glass transition of supercooled liquids, in fluids confined to thin films, in the structural arrest of particles such as granular materials, and in foams which must be driven by an applied stress in order to flow. Because jamming occurs at the transition between where a flow occurs and where motion stops, it is hoped that there may be a universal feature that describes this transition in all systems.
This volume shows that the systems described above share many common phenomenological features, and covers work done by a wide range of scientists and technologists working in areas from physics to chemistry to chemical and mechanical engineering.
Liu, Andrea J.; Nagel, Sidney R.
