Logarithmic coarsening in the Coulomb glass

Preeti Bhandari; Vikas Malik; Sanjay Puri

doi:10.1103/PhysRevE.99.052113

Logarithmic coarsening in the Coulomb glass

Preeti Bhandari, Vikas Malik, Sanjay Puri

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

8 Scopus citations

Abstract

We present numerical results from a comprehensive Monte Carlo study in two dimensions (d=2) of coarsening kinetics in the Coulomb glass (CG) model at half-filling. The CG model is characterized by spin-spin interactions which are long-range Coulombic and antiferromagnetic. For the nonequilibrium properties studied by us (spatial correlation functions and domain growth laws), we find that domain growth in the CG is analogous to that in the nearest-neighbor random-field Ising model. The domain length scale L(t) shows a crossover from a regime of "power-law growth with a disorder-dependent exponent" [L(t)∼t1/z] to a regime of "logarithmic growth with a universal exponent" [L(t)∼(lnt)1/ψ].

Original language	English
Article number	052113
Journal	Physical Review E
Volume	99
Issue number	5
DOIs	https://doi.org/10.1103/PhysRevE.99.052113
State	Published - 13 May 2019
Externally published	Yes

ASJC Scopus subject areas

Statistical and Nonlinear Physics
Statistics and Probability
Condensed Matter Physics

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10.1103/PhysRevE.99.052113

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title = "Logarithmic coarsening in the Coulomb glass",

abstract = "We present numerical results from a comprehensive Monte Carlo study in two dimensions (d=2) of coarsening kinetics in the Coulomb glass (CG) model at half-filling. The CG model is characterized by spin-spin interactions which are long-range Coulombic and antiferromagnetic. For the nonequilibrium properties studied by us (spatial correlation functions and domain growth laws), we find that domain growth in the CG is analogous to that in the nearest-neighbor random-field Ising model. The domain length scale L(t) shows a crossover from a regime of {"}power-law growth with a disorder-dependent exponent{"} [L(t)∼t1/z] to a regime of {"}logarithmic growth with a universal exponent{"} [L(t)∼(lnt)1/ψ].",

author = "Preeti Bhandari and Vikas Malik and Sanjay Puri",

note = "Funding Information: S.P. is grateful to the Department of Science and Technology, India, for funding via a J.C. Bose Fellowship Publisher Copyright: {\textcopyright} 2019 American Physical Society.",

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doi = "10.1103/PhysRevE.99.052113",

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AU - Bhandari, Preeti

AU - Malik, Vikas

AU - Puri, Sanjay

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N2 - We present numerical results from a comprehensive Monte Carlo study in two dimensions (d=2) of coarsening kinetics in the Coulomb glass (CG) model at half-filling. The CG model is characterized by spin-spin interactions which are long-range Coulombic and antiferromagnetic. For the nonequilibrium properties studied by us (spatial correlation functions and domain growth laws), we find that domain growth in the CG is analogous to that in the nearest-neighbor random-field Ising model. The domain length scale L(t) shows a crossover from a regime of "power-law growth with a disorder-dependent exponent" [L(t)∼t1/z] to a regime of "logarithmic growth with a universal exponent" [L(t)∼(lnt)1/ψ].

AB - We present numerical results from a comprehensive Monte Carlo study in two dimensions (d=2) of coarsening kinetics in the Coulomb glass (CG) model at half-filling. The CG model is characterized by spin-spin interactions which are long-range Coulombic and antiferromagnetic. For the nonequilibrium properties studied by us (spatial correlation functions and domain growth laws), we find that domain growth in the CG is analogous to that in the nearest-neighbor random-field Ising model. The domain length scale L(t) shows a crossover from a regime of "power-law growth with a disorder-dependent exponent" [L(t)∼t1/z] to a regime of "logarithmic growth with a universal exponent" [L(t)∼(lnt)1/ψ].

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Logarithmic coarsening in the Coulomb glass

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