Displacement Correlations in Disordered Athermal Networks

We derive exact results for correlations in the displacement fields { δ r } ≡ { δ r μ = x , y } in near-crystalline athermal systems in two dimensions. We analyze the displacement correlations produced by different types of microscopic disorder, and show that disorder at the microscopic scale gives...

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Published in	Journal of statistical physics Vol. 189; no. 2
Main Authors	Das, Debankur, Acharya, Pappu, Ramola, Kabir
Format	Journal Article
Language	English
Published	New York Springer US 01.11.2022 Springer Springer Nature B.V
Subjects	Analysis Bonds Disks Displacement Mathematical and Computational Physics Mathematical models Numerical analysis Numerical prediction Physical Chemistry Physics Physics and Astronomy Polydispersity Quantum Physics Statistical Physics and Dynamical Systems Stiffness Theoretical Two dimensional analysis Random pinning Green’s function techniques Near crystalline systems Bond disorder Polydispersity
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ISSN	0022-4715 1572-9613
DOI	10.1007/s10955-022-02981-9

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Abstract	We derive exact results for correlations in the displacement fields { δ r } ≡ { δ r μ = x , y } in near-crystalline athermal systems in two dimensions. We analyze the displacement correlations produced by different types of microscopic disorder, and show that disorder at the microscopic scale gives rise to long-range correlations with a dependence on the system size L given by ⟨ δ r μ δ r ν ⟩ ∼ c μ ν ( r / L , θ ) . In addition, we show that polydispersity in the constituent particle sizes and random bond disorder give rise to a logarithmic system size scaling, with c μ ν ( ρ , θ ) ∼ const μ ν - a μ ν ( θ ) log ρ + b μ ν ( θ ) ρ 2 for ρ ( = r / L ) → 0 . This scaling is different for the case of displacement correlations produced by random external forces at each vertex of the network, given by c μ ν f ( ρ , θ ) ∼ const μ ν f - ( a μ ν f ( θ ) + b μ ν f ( θ ) log ρ ) ρ 2 . Additionally, we find that correlations produced by polydispersity and the correlations produced by disorder in bond stiffness differ in their symmetry properties. Finally, we also predict the displacement correlations for a model of polydispersed soft disks subject to external pinning forces, that involve two different types of microscopic disorder. We verify our theoretical predictions using numerical simulations of polydispersed soft disks with random spring contacts in two dimensions.
AbstractList	We derive exact results for correlations in the displacement fields {δr}≡{δrμ=x,y} in near-crystalline athermal systems in two dimensions. We analyze the displacement correlations produced by different types of microscopic disorder, and show that disorder at the microscopic scale gives rise to long-range correlations with a dependence on the system size L given by ⟨δrμδrν⟩∼cμν(r/L,θ). In addition, we show that polydispersity in the constituent particle sizes and random bond disorder give rise to a logarithmic system size scaling, with cμν(ρ,θ)∼constμν-aμν(θ)logρ+bμν(θ)ρ2 for ρ(=r/L)→0. This scaling is different for the case of displacement correlations produced by random external forces at each vertex of the network, given by cμνf(ρ,θ)∼constμνf-(aμνf(θ)+bμνf(θ)logρ)ρ2. Additionally, we find that correlations produced by polydispersity and the correlations produced by disorder in bond stiffness differ in their symmetry properties. Finally, we also predict the displacement correlations for a model of polydispersed soft disks subject to external pinning forces, that involve two different types of microscopic disorder. We verify our theoretical predictions using numerical simulations of polydispersed soft disks with random spring contacts in two dimensions. We derive exact results for correlations in the displacement fields [Formula omitted] in near-crystalline athermal systems in two dimensions. We analyze the displacement correlations produced by different types of microscopic disorder, and show that disorder at the microscopic scale gives rise to long-range correlations with a dependence on the system size L given by [Formula omitted]. In addition, we show that polydispersity in the constituent particle sizes and random bond disorder give rise to a logarithmic system size scaling, with [Formula omitted] for [Formula omitted]. This scaling is different for the case of displacement correlations produced by random external forces at each vertex of the network, given by [Formula omitted]. Additionally, we find that correlations produced by polydispersity and the correlations produced by disorder in bond stiffness differ in their symmetry properties. Finally, we also predict the displacement correlations for a model of polydispersed soft disks subject to external pinning forces, that involve two different types of microscopic disorder. We verify our theoretical predictions using numerical simulations of polydispersed soft disks with random spring contacts in two dimensions. We derive exact results for correlations in the displacement fields { δ r } ≡ { δ r μ = x , y } in near-crystalline athermal systems in two dimensions. We analyze the displacement correlations produced by different types of microscopic disorder, and show that disorder at the microscopic scale gives rise to long-range correlations with a dependence on the system size L given by ⟨ δ r μ δ r ν ⟩ ∼ c μ ν ( r / L , θ ) . In addition, we show that polydispersity in the constituent particle sizes and random bond disorder give rise to a logarithmic system size scaling, with c μ ν ( ρ , θ ) ∼ const μ ν - a μ ν ( θ ) log ρ + b μ ν ( θ ) ρ 2 for ρ ( = r / L ) → 0 . This scaling is different for the case of displacement correlations produced by random external forces at each vertex of the network, given by c μ ν f ( ρ , θ ) ∼ const μ ν f - ( a μ ν f ( θ ) + b μ ν f ( θ ) log ρ ) ρ 2 . Additionally, we find that correlations produced by polydispersity and the correlations produced by disorder in bond stiffness differ in their symmetry properties. Finally, we also predict the displacement correlations for a model of polydispersed soft disks subject to external pinning forces, that involve two different types of microscopic disorder. We verify our theoretical predictions using numerical simulations of polydispersed soft disks with random spring contacts in two dimensions.
ArticleNumber	26
Audience	Academic
Author	Das, Debankur Acharya, Pappu Ramola, Kabir
Author_xml	– sequence: 1 givenname: Debankur surname: Das fullname: Das, Debankur email: debankurd@tifrh.res.in organization: Centre for Interdisciplinary Sciences, Tata Institute of Fundamental Research – sequence: 2 givenname: Pappu surname: Acharya fullname: Acharya, Pappu organization: Centre for Interdisciplinary Sciences, Tata Institute of Fundamental Research – sequence: 3 givenname: Kabir surname: Ramola fullname: Ramola, Kabir organization: Centre for Interdisciplinary Sciences, Tata Institute of Fundamental Research
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Snippet	We derive exact results for correlations in the displacement fields { δ r } ≡ { δ r μ = x , y } in near-crystalline athermal systems in two dimensions. We... We derive exact results for correlations in the displacement fields [Formula omitted] in near-crystalline athermal systems in two dimensions. We analyze the... We derive exact results for correlations in the displacement fields {δr}≡{δrμ=x,y} in near-crystalline athermal systems in two dimensions. We analyze the...
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SubjectTerms	Analysis Bonds Disks Displacement Mathematical and Computational Physics Mathematical models Numerical analysis Numerical prediction Physical Chemistry Physics Physics and Astronomy Polydispersity Quantum Physics Statistical Physics and Dynamical Systems Stiffness Theoretical Two dimensional analysis
Title	Displacement Correlations in Disordered Athermal Networks
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