Lifshits Tails for Squared Potentials

Kirsch, Werner; Raikov, Georgi

doi:10.1007/s00023-018-0680-8

Cited by 2 publications

(3 citation statements)

References 19 publications

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“…Decades of study uncovered the thermal properties of glasses, particularly their exponentially slow time behaviour in reaching equilibrium at low-temperatures 1 . This behaviour can be natural in weakly disordered systems where, in the core of the Lifshitz tails 2–5 , the Helmholtz free energy behaves like as well as for some gases at low temperatures 6 ( σ amount of disorder and T temperature). However, as pointed out by Chamon 7 , thermodynamic glass behaviour may exist in ordered systems.…”

Section: Introductionmentioning

confidence: 94%

Dimensional ensemble and (topological) fracton thermodynamics: the slow route to equilibrium

Flores

2019

Sci Rep

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The use of the dimensional-ensemble becomes compulsory when spatial dimensions are not well defined. Consequently, apart from temperature, thermodynamic equilibrium requires an additional configurational parameter. Two representative cases are considered in detail: oscillators with undefined spatial dimension and topological fractons. Spatial dimension and energy are determined as a function of temperature in both cases. At low temperatures, specific heat behaves exponentially, meaning it creates a slow route to equilibrium. In accordance with experiments, calculations suggest that the spatial dimension diminishes when temperature decreases. Parameter values are computed using data obtained from almost two-dimensional graphene and porous compounds.

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Section: Introductionmentioning

confidence: 94%

Dimensional ensemble and (topological) fracton thermodynamics: the slow route to equilibrium

Flores

2019

Sci Rep

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“…In Section 4, we formulate and prove our main results on the Lifshits tails for N, applying the estimates obtained in Section 3, as well as certain results on the Lifshits tails for the operator hθ ,ǫ . Some of these necessary results turned out to be available in the literature (see [18,27]) and some of them are borrowed from our companion paper [15] where Lifshits tails for Schrödinger operators with squared Anderson-type potentials are investigated in any dimension d ≥ 1.…”

Section: Introductionmentioning

confidence: 99%

“…In Subsection 4.1 we consider single-site twisting w of power-like decay while in Subsection 4.2 we handle the case of compactly supported w.4.1.Single-site twisting w of power-like decay. The following proposition contains results from[15] on the Lifshits tails for 1D Schrödinger operators with squared random Anderson-type potentials.Proposition 4.1 ([15, Theorem 1]). Assume (3.3).…”

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confidence: 99%

Lifshits Tails for Randomly Twisted Quantum Waveguides

Kirsch¹,

Krejčiřı́k²,

Raikov³

2018

J Stat Phys

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We consider the Dirichlet Laplacian H γ on a 3D twisted waveguide with random Anderson-type twisting γ. We introduce the integrated density of states N γ for the operator H γ , and investigate the Lifshits tails of N γ , i.e. the asymptotic behavior of N γ (E) as E ↓ inf supp dN γ . In particular, we study the dependence of the Lifshits exponent on the decay rate of the single-site twisting at infinity.

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Lifshits Tails for Squared Potentials

Abstract: We consider Schrödinger operators with a random potential which is the square of an alloy-type potential. We investigate their integrated density of states and prove Lifshits tails. Our interest in this type of models is triggered by an investigation of randomly twisted waveguides.

Cited by 2 publications

References 19 publications

Dimensional ensemble and (topological) fracton thermodynamics: the slow route to equilibrium

Dimensional ensemble and (topological) fracton thermodynamics: the slow route to equilibrium

Lifshits Tails for Randomly Twisted Quantum Waveguides

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