Possibility of Solid-Fluid Transition in Moving Periodic Systems(Condensed Matter: Structure, Mechanical and Thermal Properties)
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概要
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The steady sliding state of periodic structures such as charge density waves and flux line lattices is numerically studied based on the three dimensional driven random-field XY model. We focus on the dynamical phase transition between plastic flow and moving solid phases controlled by the magnitude of the driving force. By analyzing the connectivity of comoving clusters, we find that they percolate the system under driving forces larger than a certain critical force within a finite observation time. The critical force, however, logarithmically diverges with the observation time, i.e., the moving solid phase exists only within a certain finite time, which exponentially grows with driving force.
- 社団法人日本物理学会の論文
- 2005-07-15
著者
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Nogawa Tomoaki
Division Of Physics Graduate School Of Science Hokkaido University
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Yoshino H
Institute For Solid State Physics University Of Tokyo
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Yoshino Hajime
Department Of Earth And Space Science School Of Science Osaka University
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Yoshino Hajime
Department Of Earth And Space Science Faculty Of Science Osaka University
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NOGAWA Tomoaki
School of Science, Osaka University
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YOSHINO Hajime
School of Science, Osaka University
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MATSUKAWA Hiroshi
College of Science and Engineering, Aoyama Gakuin University
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Matsukawa Hiroshi
Department Of Physics College Of Science And Engineering Aoyama Gakuin University
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- Possibility of Solid-Fluid Transition in Moving Periodic Systems(Condensed Matter: Structure, Mechanical and Thermal Properties)
- Topological Defects in Moving Charge Density Waves and Flux Line Lattices
- Scaling Approach to Glassy Stationary States of Spin-Glasses under Chaos Effects
- Fragility of the Equilibrium State in the Four-Dimensional ±J Ising Spin Glass
- Topological Defects in Moving Charge Density Waves and Flux Line Lattices
- Possibility of Solid-Fluid Transition in Moving Periodic Systems(Condensed Matter: Structure, Mechanical and Thermal Properties)