Fluctuations of the free energy in the REM and the $p$-spin SK models

Bovier, Anton; Kurkova, Irina; Löwe, Matthias

doi:10.1214/aop/1023481004

Cited by 90 publications

(126 citation statements)

References 27 publications

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“…Eisele [8] and Olivieri and Picco [13] have rigorously derived the limit (1.3) (in probability and a.s.) and also extended this result to the case where X i have the Weibull-type tail (1.2) (case B). 1 Recently, a detailed analysis of the limit laws for Z n (β) in the Gaussian case has been accomplished by Bovier et al [6]. In particular, is has been shown that in addition to the phase transition at the critical point β c , manifested as the LLN breakdown for β > β c , within the region β < β c there is a second phase transition atβ c = log 2/2 = 1 2 β c , in that for β >β c the fluctuations of Z n (β) become non-Gaussian.…”

Section: Random Energy Modelmentioning

confidence: 99%

“…In the present work, we extend these results to the class of distributions with Weibull/Fréchet-type tails of the form (1.2). As compared to the paper [6] which proceeded from extreme value theory, we use methods of theory of summation of independent random variables. This general and powerful approach simplifies the proofs and in particular reveals that non-Gaussian limit laws are in fact stable.…”

Section: Random Energy Modelmentioning

confidence: 99%

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Limit theorems for sums of random exponentials

Arous

Bogachev

Molchanov

2005

Probab. Theory Relat. Fields

100

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Abstract. We study limiting distributions of exponential sums SN (t) = N i=1 e tX i as t → ∞, N → ∞, where (Xi) are i.i.d. random variables. Two cases are considered: (A) ess sup Xi = 0 and (B) ess sup Xi = ∞. We assume that the function h(x) = − log P{Xi > x} (case B) or h(x) = − log P{Xi > −1/x} (case A) is regularly varying at ∞ with index 1 < ̺ < ∞ (case B) or 0 < ̺ < ∞ (case A). The appropriate growth scale of N relative to t is of the form e λH 0 (t) (0 < λ < ∞), where the rate function H0(t) is a certain asymptotic version of the function H(t) = log E[e tX i ] (case B) or H(t) = − log E[e tX i ] (case A). We have found two critical points, λ1 < λ2, below which the Law of Large Numbers and the Central Limit Theorem, respectively, break down. For 0 < λ < λ2, under the slightly stronger condition of normalized regular variation of h we prove that the limit laws are stable, with characteristic exponent α = α(̺, λ) ∈ (0, 2) and skewness parameter β ≡ 1.

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Section: Random Energy Modelmentioning

confidence: 99%

Section: Random Energy Modelmentioning

confidence: 99%

Limit theorems for sums of random exponentials

Arous

Bogachev

Molchanov

2005

Probab. Theory Relat. Fields

100

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“…In the appropriate scaling limit, the appearance of the bias is abrupt and corresponds to a phase transition in variants of the random energy model (REM) [20][21][22][23][24]. The connection between the random energy model and the Jarzynski estimator of free energy differences was first made in Refs.…”

Section: Introductionmentioning

confidence: 99%

Phase transition in the Jarzynski estimator of free energy differences

2012

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The transition between a regime in which thermodynamic relations apply only to ensembles of small systems coupled to a large environment and a regime in which they can be used to characterize individual macroscopic systems is analyzed in terms of the change in behavior of the Jarzynski estimator of equilibrium free energy differences from nonequilibrium work measurements. Given a fixed number of measurements, the Jarzynski estimator is unbiased for sufficiently small systems. In these systems the directionality of time is poorly defined and the configurations that dominate the empirical average, but which are in fact typical of the reverse process, are sufficiently well sampled. As the system size increases the arrow of time becomes better defined. The dominant atypical fluctuations become rare and eventually cannot be sampled with the limited resources that are available. Asymptotically, only typical work values are measured. The Jarzynski estimator becomes maximally biased and approaches the exponential of minus the average work, which is the result that is expected from standard macroscopic thermodynamics. In the proper scaling limit, this regime change has been recently described in terms of a phase transition in variants of the random energy model. In this paper this correspondence is further demonstrated in two examples of physical interest: the sudden compression of an ideal gas and adiabatic quasistatic volume changes in a dilute real gas.

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“…The point process ͑1.18͒ is the limiting object which appears in the REM. 15 Indeed, in this case t ‫ء‬ ͑0͒ =0, and, hence, ͑0͒ = M͑0͒ = ͱ 2 log 2, which in turn implies that the scaling constants ͑1.15͒ and ͑1.16͒ coincide with that of the REM without external field.…”

Section: ͑117͒mentioning

confidence: 84%

Fluctuations of the partition function in the generalized random energy model with external field

Bovier

Klimovsky

2008

Journal of Mathematical Physics

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We study Derrida's generalized random energy model ͑GREM͒ in the presence of uniform external field. We compute the fluctuations of the ground state and of the partition function in the thermodynamic limit for all admissible values of parameters. We find that the fluctuations are described by a hierarchical structure which is obtained by a certain coarse graining of the initial hierarchical structure of the GREM with external field. We provide an explicit formula for the free energy of the model. We also derive some large deviation results providing an expression for the free energy in a class of models with Gaussian Hamiltonians and external field. Finally, we prove that the coarse-grained parts of the system emerging in the thermodynamic limit tend to have a certain optimal magnetization, as prescribed by the strength of the external field and by parameters of the GREM.

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Fluctuations of the free energy in the REM and the $p$-spin SK models

Cited by 90 publications

References 27 publications

Limit theorems for sums of random exponentials

Limit theorems for sums of random exponentials

Phase transition in the Jarzynski estimator of free energy differences

Fluctuations of the partition function in the generalized random energy model with external field

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