Microcanonical entropy for small magnetizations

Behrinǵer, Hans

doi:10.1088/0305-4470/37/4/026

Cited by 11 publications

(21 citation statements)

References 19 publications

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“…For more details see Section III and in particular Reference [26]. Note also that other microcanonical quantities like the spontaneous magnetization and the susceptibility also exhibit typical features of continuous phase transitions in finite systems [19,20,21,22,25,27]. These aspects are however not studied in the present work.…”

Section: Signatures Of Phase Transitions In the Microcanonical Spmentioning

confidence: 91%

“…These features are accompanied by singular physical quantities [18,19,20,21,22,23,24,25,26,27]. The associated singularities, however, are not the consequence of a non-analytic microcanonical entropy and can therefore be characterized by classical critical exponents [19,22]. Similarly, intriguing features are also revealed in the microcanonical entropy of small systems with a discontinuous transition in the infinite volume limit [5,28,29,30,31,32,33].…”

Section: Introductionmentioning

confidence: 99%

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Continuous phase transitions with a convex dip in the microcanonical entropy

Behrinǵer

Pleimling

2006

Phys. Rev. E

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The appearance of a convex dip in the microcanonical entropy of finite systems usually signals a first order transition. However, a convex dip also shows up in some systems with a continuous transition as, for example, in the Baxter-Wu model and in the four-state Potts model in two dimensions. We demonstrate that the appearance of a convex dip in those cases can be traced back to a finite-size effect. The properties of the dip are markedly different from those associated with a first order transition and can be understood within a microcanonical finite-size scaling theory for continuous phase transitions. Results obtained from numerical simulations corroborate the predictions of the scaling theory.

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Section: Signatures Of Phase Transitions In the Microcanonical Spmentioning

confidence: 91%

Section: Introductionmentioning

confidence: 99%

Continuous phase transitions with a convex dip in the microcanonical entropy

Behrinǵer

Pleimling

2006

Phys. Rev. E

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“…The entropy surface exhibits a well-defined transition point at an energy E c and magnetization M c although in finite systems S N (E, M) is everywhere perfectly analytic. The microcanonical analysis also shows that typical features of symmetry breaking, as for example the abrupt onset of several order parameter branches when the transition point is crossed from above, are already encountered in small systems [5,6,7]. With regard to these intriguing effects, it is tempting to ask whether a direct analysis of the microcanonical entropy also allows the determination of critical quantities from finite-size data.…”

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confidence: 99%

“…Here β, α, and ν are the canonical critical exponents. As the microcanonical order parameter varies like a square root in the vicinity of ε c,N for all finite system sizes N [5,7] the scaling function W is asymptotically given as a square root W (x) ∼ √ x for small scaling variables x. One remarkable feature of equation (5) is the absence of any non-universal quantity related to the infinite system.…”

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confidence: 99%

“…The expected universality of the scaling function for a given universality class has been demonstrated. The microcanonical finite-size scaling theory, presented for the order parameter in the present work, can also be formulated more generally in terms of scaling relations of the entropy of finite systems considered as a function of the energy, the magnetization and the inverse system size [17].…”

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Microcanonical scaling in small systems

2004

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A microcanonical finite-size scaling ansatz is discussed. It exploits the existence of a well-defined transition point for systems of finite size in the microcanonical ensemble. The best data collapse obtained for small systems yields values for the critical exponents in good agreement with other approaches. The exact location of the infinite system critical point is not needed when extracting critical exponents from the microcanonical finite-size scaling theory.

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On the Mean-Field Spherical Model

Kastner

Schnetz

2006

J Stat Phys

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Exact solutions are obtained for the mean-field spherical model, with or without an external magnetic field, for any finite or infinite number N of degrees of freedom, both in the microcanonical and in the canonical ensemble. The canonical result allows for an exact discussion of the loci of the Fisher zeros of the canonical partition function. The microcanonical entropy is found to be nonanalytic for arbitrary finite N . The mean-field spherical model of finite size N is shown to be equivalent to a mixed isovector/isotensor σ-model on a lattice of two sites. Partial equivalence of statistical ensembles is observed for the mean-field spherical model in the thermodynamic limit. A discussion of the topology of certain state space submanifolds yields insights into the relation of these topological quantities to the thermodynamic behavior of the system in the presence of ensemble nonequivalence.Key Words: Phase transitions, spherical model, microcanonical, canonical, ensemble nonequivalence, partial equivalence, Fisher zeros of the partition function, ÊÈ N −1 σ-model, mixed isovector/isotensor σ-model, model equivalence, topological approach.

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Microcanonical entropy for small magnetizations

Cited by 11 publications

References 19 publications

Continuous phase transitions with a convex dip in the microcanonical entropy

Continuous phase transitions with a convex dip in the microcanonical entropy

Microcanonical scaling in small systems

On the Mean-Field Spherical Model

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