Your search keyword '"ensemble inequivalence"' showing total 41 results

1. Random Transitions of a Binary Star in the Canonical Ensemble.

Author

Chavanis, Pierre-Henri

Subjects

*METASTABLE states, *FIRST-order phase transitions, *CANONICAL ensemble, *GRAVITATIONAL interactions, *THERMODYNAMIC potentials, *FOKKER-Planck equation

Abstract

After reviewing the peculiar thermodynamics and statistical mechanics of self-gravitating systems, we consider the case of a "binary star" consisting of two particles of size a in gravitational interaction in a box of radius R. The caloric curve of this system displays a region of negative specific heat in the microcanonical ensemble, which is replaced by a first-order phase transition in the canonical ensemble. The free energy viewed as a thermodynamic potential exhibits two local minima that correspond to two metastable states separated by an unstable maximum forming a barrier of potential. By introducing a Langevin equation to model the interaction of the particles with the thermal bath, we study the random transitions of the system between a "dilute" state, where the particles are well separated, and a "condensed" state, where the particles are bound together. We show that the evolution of the system is given by a Fokker–Planck equation in energy space and that the lifetime of a metastable state is given by the Kramers formula involving the barrier of free energy. This is a particular case of the theory developed in a previous paper (Chavanis, 2005) for N Brownian particles in gravitational interaction associated with the canonical ensemble. In the case of a binary star ( N = 2 ), all the quantities can be calculated exactly analytically. We compare these results with those obtained in the mean field limit N → + ∞ . [ABSTRACT FROM AUTHOR]

Published

2024

2. Random Transitions of a Binary Star in the Canonical Ensemble

Author

Pierre-Henri Chavanis

Subjects

statistical mechanics, self-gravitating systems, ensemble inequivalence, metastable states, random transitions, Fokker–Planck equation, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

After reviewing the peculiar thermodynamics and statistical mechanics of self-gravitating systems, we consider the case of a “binary star” consisting of two particles of size a in gravitational interaction in a box of radius R. The caloric curve of this system displays a region of negative specific heat in the microcanonical ensemble, which is replaced by a first-order phase transition in the canonical ensemble. The free energy viewed as a thermodynamic potential exhibits two local minima that correspond to two metastable states separated by an unstable maximum forming a barrier of potential. By introducing a Langevin equation to model the interaction of the particles with the thermal bath, we study the random transitions of the system between a “dilute” state, where the particles are well separated, and a “condensed” state, where the particles are bound together. We show that the evolution of the system is given by a Fokker–Planck equation in energy space and that the lifetime of a metastable state is given by the Kramers formula involving the barrier of free energy. This is a particular case of the theory developed in a previous paper (Chavanis, 2005) for N Brownian particles in gravitational interaction associated with the canonical ensemble. In the case of a binary star (N=2), all the quantities can be calculated exactly analytically. We compare these results with those obtained in the mean field limit N→+∞.

Published

2024

3. Ensemble inequivalence in a generalized XY model.

Author

Yu, Shao-Bo, Xu, Ren, and Hou, Ji-Xuan

Subjects

*MONTE Carlo method, *FIRST-order phase transitions, *PHASE diagrams, *CANONICAL ensemble, *PHASE transitions

Abstract

In this paper, we propose a new generalized XY model with nearest-neighbor interaction which cannot be studied analytically. By adopting both the canonical Monte Carlo simulations and the microcanonical Monte Carlo simulations, the first-order phase transitions in both canonical ensemble and microcanonical ensemble are observed numerically, and the accurate phase-transition temperatures of the model with different parameters are given. From the distinct phase diagrams in two different ensembles, we conclude that the model we propose here exists as an ensemble equivalence. [ABSTRACT FROM AUTHOR]

Published

2023

4. Computation of Microcanonical Entropy at Fixed Magnetization Without Direct Counting.

Author

Campa, Alessandro, Gori, Giacomo, Hovhannisyan, Vahan, Ruffo, Stefano, and Trombettoni, Andrea

Abstract

We discuss a method to compute the microcanonical entropy at fixed magnetization without direct counting. Our approach is based on the evaluation of a saddle-point leading to an optimization problem. The method is applied to a benchmark Ising model with simultaneous presence of mean-field and nearest-neighbour interactions for which direct counting is indeed possible, thus allowing a comparison. Moreover, we apply the method to an Ising model with mean-field, nearest-neighbour and next-nearest-neighbour interactions, for which direct counting is not straightforward. For this model, we compare the solution obtained by our method with the one obtained from the formula for the entropy in terms of all correlation functions. This example shows that for general couplings our method is much more convenient than direct counting methods to compute the microcanonical entropy at fixed magnetization. [ABSTRACT FROM AUTHOR]

Published

2021

5. Liquid–Gas phase transition in nuclei.

Author

Borderie, B. and Frankland, J.D.

Subjects

*PHASE transitions

Abstract

Abstract This review article takes stock of the progress made in understanding the phase transition in hot nuclei and highlights the coherence of observed signatures. [ABSTRACT FROM AUTHOR]

Published

2019

6. Participation Ratio for Constraint-Driven Condensation with Superextensive Mass.

Author

Gradenigo, Giacomo and Bertin, Eric

Subjects

*RANDOM variables, *CONDENSATION reactions, *GLASS transitions, *CONSERVATION laws (Physics), *MATHEMATICAL constants

Abstract

Broadly distributed random variables with a power-law distribution f (m) ~ m -(1+α) are known to generate condensation effects. This means that, when the exponent a lies in a certain interval, the largest variable in a sum of N (independent and identically distributed) terms is for large N of the same order as the sum itself. In particular, when the distribution has infinite mean (0 < α < 1) one finds unconstrained condensation, whereas for α > 1 constrained condensation takes places fixing the total mass to a large enough value ... > Mc. In both cases, a standard indicator of the condensation phenomenon is the participation ratio ..., which takes a finite value for N → ∞ when condensation occurs. To better understand the connection between constrained and unconstrained condensation, we study here the situation when the total mass is fixed to a superextensive value M ~ N 1+ δ (δ > 0), hence interpolating between the unconstrained condensation case (where the typical value of the total mass scales as M ~ N1/α for α < 1) and the extensive constrained mass. In particular we show that for exponents a < 1 a condensate phase for values δ > δc = 1/α - 1 is separated from a homogeneous phase at δ < δc from a transition line, δ = δc, where a weak condensation phenomenon takes place. We focus on the evaluation of the participation ratio as a generic indicator of condensation, also recalling or presenting results in the standard cases of unconstrained mass and of fixed extensive mass. [ABSTRACT FROM AUTHOR]

Published

2017

7. The world of long-range interactions: A bird's eye view.

Author

Gupta, Shamik and Ruffo, Stefano

Subjects

*THERMODYNAMIC equilibrium, *DYNAMICAL systems, *STATISTICAL mechanics, *AERIAL views, *KINETIC theory of matter

Abstract

In recent years, studies of long-range interacting (LRI) systems have taken center stage in the arena of statistical mechanics and dynamical system studies, due to new theoretical developments involving tools from as diverse a field as kinetic theory, non-equilibrium statistical mechanics, and large deviation theory, but also due to new and exciting experimental realizations of LRI systems. In the first, introductory, Section 1, we discuss the general features of long-range interactions, emphasizing in particular the main physical phenomenon of non-additivity, which leads to a plethora of distinct effects, both thermodynamic and dynamic, that are not observed with short-range interactions: Ensemble inequivalence, slow relaxation, broken ergodicity. In Section 2, we discuss several physical systems with long-range interactions: mean-field spin systems, self-gravitating systems, Euler equations in two dimensions, Coulomb systems, one-component electron plasma, dipolar systems, free-electron lasers. In Section 3, we discuss the general scenario of dynamical evolution of generic LRI systems. In Section 4, we discuss an illustrative example of LRI systems, the Kardar-Nagel spin system, which involves discrete degrees of freedom, while in Section 5, we discuss a paradigmatic example involving continuous degrees of freedom, the so-called Hamiltonian mean-field (HMF) model. For the former, we demonstrate the effects of ensemble inequivalence and slow relaxation, while for the HMF model, we emphasize in particular the occurrence of the so-called quasistationary states (QSSs) during relaxation towards the Boltzmann-Gibbs equilibrium state. The QSSs are non-equilibrium states with lifetimes that diverge with the system size, so that in the thermodynamic limit, the systems remain trapped in the QSSs, thereby making the latter the effective stationary states. In Section 5, we also discuss an experimental system involving atoms trapped in optical cavities, which may be modelled by the HMF system. In Section 6, we address the issue of ubiquity of the quasistationary behavior by considering a variety of models and dynamics, discussing in each case the conditions to observe QSSs. In Section 7, we investigate the issue of what happens when a long-range system is driven out of thermal equilibrium. Conclusions are drawn in Section 8. [ABSTRACT FROM AUTHOR]

Published

2017

8. Ensemble inequivalence and Maxwell construction in the self-gravitating ring model.

Author

Rocha Filho, T.M., Silvestre, C.H., and Amato, M.A.

Subjects

*GIBBS' equation, *MOLECULAR dynamics, *THERMODYNAMICS, *MONTE Carlo method, *SIMULATION methods & models

Abstract

The statement that Gibbs equilibrium ensembles are equivalent is a base line in many approaches in the context of equilibrium statistical mechanics. However, as a known fact, for some physical systems this equivalence may not be true. In this paper we illustrate from first principles the inequivalence between the canonical and microcanonical ensembles for a system with long range interactions. We make use of molecular dynamics simulations and Monte Carlo simulations to explore the thermodynamics properties of the self-gravitating ring model and discuss on what conditions the Maxwell construction is applicable. [ABSTRACT FROM AUTHOR]

Published

2018

9. Concavity, Response Functions and Replica Energy

Author

Alessandro Campa, Lapo Casetti, Ivan Latella, Agustín Pérez-Madrid, and Stefano Ruffo

Subjects

long-range interactions, non-additive systems, ensemble inequivalence, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

In nonadditive systems, like small systems or like long-range interacting systems even in the thermodynamic limit, ensemble inequivalence can be related to the occurrence of negative response functions, this in turn being connected with anomalous concavity properties of the thermodynamic potentials associated with the various ensembles. We show how the type and number of negative response functions depend on which of the quantities E, V and N (energy, volume and number of particles) are constrained in the ensemble. In particular, we consider the unconstrained ensemble in which E, V and N fluctuate, which is physically meaningful only for nonadditive systems. In fact, its partition function is associated with the replica energy, a thermodynamic function that identically vanishes when additivity holds, but that contains relevant information in nonadditive systems.

Published

2018

10. Computation of Microcanonical Entropy at Fixed Magnetization Without Direct Counting

Author

Giacomo Gori, Alessandro Campa, Stefano Ruffo, Andrea Trombettoni, V. V. Hovhannisyan, Campa, Alessandro, Gori, Giacomo, Hovhannisyan, Vahan, Ruffo, Stefano, and Trombettoni, Andrea

Subjects

Physics Statistical Mechanics, Optimization problem, Entropy, Computation, FOS: Physical sciences, Statistical Mechanics, Settore FIS/03 - Fisica della Materia, Magnetization, Physics, Ensemble inequivalence, Long-range interactions, Phase transitions, Physic, Statistical physics, Condensed Matter - Statistical Mechanics, Mathematical Physics, Saddle, Statistical Mechanics (cond-mat.stat-mech), Entropy (statistical thermodynamics), Statistical Mechanic, Statistical and Nonlinear Physics, Settore FIS/02 - Fisica Teorica, Modelli e Metodi Matematici, Benchmark (computing), Ising model

Abstract

We discuss a method to compute the microcanonical entropy at fixed magnetization without direct counting. Our approach is based on the evaluation of a saddle-point leading to an optimization problem. The method is applied to a benchmark Ising model with simultaneous presence of mean-field and nearest-neighbour interactions for which direct counting is indeed possible, thus allowing a comparison. Moreover, we apply the method to an Ising model with mean-field, nearest-neighbour and next-nearest-neighbour interactions, for which direct counting is not straightforward. For this model, we compare the solution obtained by our method with the one obtained from the formula for the entropy in terms of all correlation functions. This example shows that for general couplings our method is much more convenient than direct counting methods to compute the microcanonical entropy at fixed magnetization., Comment: 41 pages, 9 figures, in press in Journal of Statistical Physics

Published

2021

11. Participation Ratio for Constraint-Driven Condensation with Superextensive Mass

Author

Giacomo Gradenigo and Eric Bertin

Subjects

large deviations, condensation phenomenon, ensemble inequivalence, canonical ensemble, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

Broadly distributed random variables with a power-law distribution f ( m ) ∼ m - ( 1 + α ) are known to generate condensation effects. This means that, when the exponent α lies in a certain interval, the largest variable in a sum of N (independent and identically distributed) terms is for large N of the same order as the sum itself. In particular, when the distribution has infinite mean ( 0 < α < 1 ) one finds unconstrained condensation, whereas for α > 1 constrained condensation takes places fixing the total mass to a large enough value M = ∑ i = 1 N m i > M c . In both cases, a standard indicator of the condensation phenomenon is the participation ratio Y k = 〈 ∑ i m i k / ( ∑ i m i ) k 〉 ( k > 1 ), which takes a finite value for N → ∞ when condensation occurs. To better understand the connection between constrained and unconstrained condensation, we study here the situation when the total mass is fixed to a superextensive value M ∼ N 1 + δ ( δ > 0 ), hence interpolating between the unconstrained condensation case (where the typical value of the total mass scales as M ∼ N 1 / α for α < 1 ) and the extensive constrained mass. In particular we show that for exponents α < 1 a condensate phase for values δ > δ c = 1 / α - 1 is separated from a homogeneous phase at δ < δ c from a transition line, δ = δ c , where a weak condensation phenomenon takes place. We focus on the evaluation of the participation ratio as a generic indicator of condensation, also recalling or presenting results in the standard cases of unconstrained mass and of fixed extensive mass.

Published

2017

12. Monte Carlo simulations in the unconstrained ensemble

Author

Pierfrancesco Di Cintio, Stefano Ruffo, Alessandro Campa, Lapo Casetti, J. Miguel Rubi, and Ivan Latella

Subjects

Thirring model, Estadística matemàtica, Long-range interactions, ensemble inequivalence, Thirring model, Work (thermodynamics), Computer science, Monte Carlo method, Physical system, FOS: Physical sciences, 01 natural sciences, Partícules (Matèria), ensemble inequivalence, Settore FIS/03 - Fisica della Materia, 010305 fluids & plasmas, Completely open systems, Control parameters, External conditions, Intensive variables, Long range interactions, Macroscopic systems, Monte carlo algorithms, 0103 physical sciences, Range (statistics), Statistical physics, 010306 general physics, Mètode de Montecarlo, Monte Carlo algorithm, Condensed Matter - Statistical Mechanics, Statistical Mechanics (cond-mat.stat-mech), Settore FIS/02 - Fisica Teorica, Modelli e Metodi Matematici, Long-range interactions, Mathematical statistics, Particles

Abstract

The unconstrained ensemble describes completely open systems whose control parameters are chemical potential, pressure, and temperature. For macroscopic systems with short-range interactions, thermodynamics prevents the simultaneous use of these intensive variables as control parameters, because they are not independent and cannot account for the system size. When the range of the interactions is comparable with the size of the system, however, these variables are not truly intensive and may become independent, so equilibrium states defined by the values of these parameters may exist. Here, we derive a Monte Carlo algorithm for the unconstrained ensemble and show that simulations can be performed using chemical potential, pressure, and temperature as control parameters. We illustrate the algorithm by applying it to physical systems where either the system has long-range interactions or is confined by external conditions. The method opens up a new avenue for the simulation of completely open systems exchanging heat, work, and matter with the environment., 7 pages, 3 figures

Published

2021

13. Ensemble Inequivalence In A XY Model With Long-Range Interactions.

Author

de Buyl, Pierre, Mukamel, David, and Ruffo, Stefano

Subjects

*MEAN field theory, *THERMODYNAMICS, *ENTROPY, *HEAT, *TEMPERATURE

Abstract

We introduce a new XY mean-field spin system whose canonical and microcanonical thermodynamics can be solved exactly. Microcanonical entropy is obtained by a novel use of large deviation techniques. The model desplays ensemble inequivalence and the presence of negative specific heat and temperature jumps in the microcanonical ensemble. © 2005 American Institute of Physics [ABSTRACT FROM AUTHOR]

Published

2005

14. Microcanonical Analysis of Exactness of the Mean-Field Theory in Long-Range Interacting Systems.

Author

Mori, Takashi

Subjects

*MEAN field theory, *STATISTICAL physics, *GRAVITATION, *EQUILIBRIUM, *ISING model, *HAMILTONIAN systems

Abstract

Classical spin systems with nonadditive long-range interactions are studied in the microcanonical ensemble. It is expected that the entropy of such a system is identical to that of the corresponding mean-field model, which is called 'exactness of the mean-field theory'. It is found out that this expectation is not necessarily true if the microcanonical ensemble is not equivalent to the canonical ensemble in the mean-field model. Moreover, necessary and sufficient conditions for exactness of the mean-field theory are obtained. These conditions are investigated for two concrete models, the α-Potts model with annealed vacancies and the α-Potts model with invisible states. [ABSTRACT FROM AUTHOR]

Published

2012

15. Thermodynamics and dynamics of systems with long-range interactions

Author

Bouchet, Freddy, Gupta, Shamik, and Mukamel, David

Subjects

*THERMODYNAMICS, *SET theory, *DIFFERENTIAL equations, *SPECIFIC heat, *STATISTICAL correlation, *PHASE transitions

Abstract

Abstract: We review simple aspects of the thermodynamic and dynamical properties of systems with long-range pairwise interactions (LRI), which decay as at large distances in dimensions. Two broad classes of such systems are discussed. (i) Systems with a slow decay of the interactions, termed “strong” LRI, where the energy is super-extensive. These systems are characterized by unusual properties such as inequivalence of ensembles, negative specific heat, slow decay of correlations, anomalous diffusion and ergodicity breaking. (ii) Systems with faster decay of the interaction potential, where the energy is additive, thus resulting in less dramatic effects. These interactions affect the thermodynamic behavior of systems near phase transitions, where long-range correlations are naturally present. Long-range correlations are often present in systems driven out of equilibrium when the dynamics involves conserved quantities. Steady state properties of driven systems with local dynamics are considered within the framework outlined above. [ABSTRACT FROM AUTHOR]

Published

2010

16. Statistical mechanics and dynamics of solvable models with long-range interactions

Author

Campa, Alessandro, Dauxois, Thierry, and Ruffo, Stefano

Subjects

*STATISTICAL mechanics, *GRAVITATIONAL fields, *HYDRODYNAMICS, *ELASTICITY, *THERMODYNAMICS, *STRUCTURAL dynamics, *TEMPERATURE effect, *SYSTEM analysis

Abstract

Abstract: For systems with long-range interactions, the two-body potential decays at large distances as , with , where is the space dimension. Examples are: gravitational systems, two-dimensional hydrodynamics, two-dimensional elasticity, charged and dipolar systems. Although such systems can be made extensive, they are intrinsically non additive: the sum of the energies of macroscopic subsystems is not equal to the energy of the whole system. Moreover, the space of accessible macroscopic thermodynamic parameters might be non convex. The violation of these two basic properties of the thermodynamics of short-range systems is at the origin of ensemble inequivalence. In turn, this inequivalence implies that specific heat can be negative in the microcanonical ensemble, and temperature jumps can appear at microcanonical first order phase transitions. The lack of convexity allows us to easily spot regions of parameter space where ergodicity may be broken. Historically, negative specific heat had been found for gravitational systems and was thought to be a specific property of a system for which the existence of standard equilibrium statistical mechanics itself was doubted. Realizing that such properties may be present for a wider class of systems has renewed the interest in long-range interactions. Here, we present a comprehensive review of the recent advances on the statistical mechanics and out-of-equilibrium dynamics of solvable systems with long-range interactions. The core of the review consists in the detailed presentation of the concept of ensemble inequivalence, as exemplified by the exact solution, in the microcanonical and canonical ensembles, of mean-field type models. Remarkably, the entropy of all these models can be obtained using the method of large deviations. Long-range interacting systems display an extremely slow relaxation towards thermodynamic equilibrium and, what is more striking, the convergence towards quasi-stationary states. The understanding of such unusual relaxation process is obtained by the introduction of an appropriate kinetic theory based on the Vlasov equation. A statistical approach, founded on a variational principle introduced by Lynden-Bell, is shown to explain qualitatively and quantitatively some features of quasi-stationary states. Generalizations to models with both short and long-range interactions, and to models with weakly decaying interactions, show the robustness of the effects obtained for mean-field models. [Copyright &y& Elsevier]

Published

2009

17. Simpler variational problems for statistical equilibria of the 2D Euler equation and other systems with long range interactions

Author

Bouchet, Freddy

Subjects

*EQUATIONS, *QUANTUM theory, *THERMODYNAMICS, *FUNCTIONAL analysis

Abstract

Abstract: The Robert–Sommeria–Miller equilibrium statistical mechanics predicts the final organization of two dimensional flows. This powerful theory is difficult to handle practically, due to the complexity associated with an infinite number of constraints. Several alternative simpler variational problems, based on Casimir’s or stream function functionals, have been considered recently. We establish the relations between all these variational problems, justifying the use of simpler formulations. [Copyright &y& Elsevier]

Published

2008

18. Ensemble inequivalence in random graphs

Author

Barré, Julien and Gonçalves, Bruno

Subjects

*ENTROPY, *THERMODYNAMICS, *PHYSICS, *DYNAMICS

Abstract

Abstract: We present a complete analytical solution of a system of Potts spins on a random k-regular graph in both the canonical and microcanonical ensembles, using the Large Deviation Cavity Method (LDCM). The solution is shown to be composed of three different branches, resulting in a non-concave entropy function. The analytical solution is confirmed with numerical Metropolis and Creutz simulations and our results clearly demonstrate the presence of a region with negative specific heat and, consequently, ensemble inequivalence between the canonical and microcanonical ensembles. [Copyright &y& Elsevier]

Published

2007

19. Negative magnetic susceptibility and nonequivalent ensembles for the mean-field spin model

Author

Campa, Alessandro, Ruffo, Stefano, and Touchette, Hugo

Subjects

*FERROMAGNETISM, *MAGNETIZATION, *INFORMATION theory, *THERMODYNAMICS

Abstract

Abstract: We calculate the thermodynamic entropy of the mean-field spin model in the microcanonical ensemble as a function of the energy and magnetization of the model. The entropy and its derivatives are obtained from the theory of large deviations, as well as from Rugh''s microcanonical formalism, which is implemented by computing averages of suitable observables in microcanonical molecular dynamics simulations. Our main finding is that the entropy is a concave function of the energy for all values of the magnetization, but is nonconcave as a function of the magnetization for some values of the energy. This last property suggests that the magnetic susceptibility of the model can be negative when calculated microcanonically for fixed values of the energy and magnetization. This provides a magnetization analogue of negative heat capacities, which are well-known to be associated in general with the inequivalence of the microcanonical and canonical ensembles. Here, the two ensembles that are nonequivalent are the microcanonical ensemble in which the energy and magnetization are held fixed and the canonical ensemble in which the energy and magnetization are fixed only on average by fixing the temperature and magnetic field. [Copyright &y& Elsevier]

Published

2007

20. An account of the statistical and dynamical properties of systems with long-range interactions

Author

Antoniazzi, Andrea and Ruffo, Stefano

Subjects

*THERMODYNAMICS, *STATISTICAL mechanics, *PHASE transitions, *QUANTUM theory

Abstract

Abstract: We shortly review recent progress in the field of long-range interactions, analyzed from the viewpoint of statistical mechanics and of dynamical systems theory. Long-range interaction potentials decay at large distance with a power that is smaller than space dimension. This feature causes a lack of additivity, which in turn implies inequivalence between microcanonical and canonical ensemble for what concerns predictions near first order canonical phase transitions. Inequivalence manifests itself physically by the presence of curious effects such as negative specific heat and temperature jumps. We also briefly mention dynamical effects which we believe are generic for long-range interactions: (i) quasi-stationary states whose lifetime increases with system size; (ii) metastable states that live proportionally to the exponential of systems size times the entropy barrier; (iii) broken ergodicity. [Copyright &y& Elsevier]

Published

2006

21. Dynamics and thermodynamics of rotators interacting with both long- and short-range couplings

Author

Campa, Alessandro, Giansanti, Andrea, Mukamel, David, and Ruffo, Stefano

Subjects

*THERMODYNAMICS, *FERROMAGNETISM, *HAMILTONIAN systems, *MEAN field theory

Abstract

Abstract: The effect of nearest-neighbor coupling on the thermodynamic and dynamical properties of the ferromagnetic Hamiltonian mean field model (HMF) is studied. For a range of antiferromagnetic nearest-neighbor coupling, a canonical first-order transition is observed, and the canonical and microcanonical ensembles are non-equivalent. In studying the relaxation time of non-equilibrium states it is found that as in the HMF model, a class of non-magnetic states is quasi-stationary, with an algebraic divergence of their lifetime with the number of degrees of freedom N. The lifetime of metastable states is found to increase exponentially with N as expected. [Copyright &y& Elsevier]

Published

2006

22. Topological approach to phase transitions and inequivalence of statistical ensembles

Author

Kastner, Michael

Subjects

*PHASE transitions, *LINEAR algebra, *MANIFOLDS (Mathematics), *DIFFERENTIAL geometry

Abstract

Abstract: The relation between thermodynamic phase transitions in classical systems and topology changes in their state space is discussed for systems in which equivalence of statistical ensembles does not hold. As an example, the spherical model with mean field-type interactions is considered. Exact results for microcanonical and canonical quantities are compared with topological properties of a certain family of submanifolds of the state space. Due to the observed ensemble inequivalence, a close relation is expected to exist only between the topological approach and one of the statistical ensembles. It is found that the observed topology changes can be interpreted meaningfully when compared to microcanonical quantities. [Copyright &y& Elsevier]

Published

2006

23. Canonical and microcanonical partition functions in long-range systems with order parameter space of arbitrary dimension

Author

Campa, Alessandro and Giansanti, Andrea

Subjects

*TEMPERATURE, *ENTROPY, *LITERATURE, *THERMODYNAMICS

Abstract

We consider systems in which the canonical partition function can be expressed as the integral in an n-dimensional space (the order parameter space) of a function that also depends parametrically on the number N of degrees of freedom and on the inverse temperature β. We show how to compute, together with the canonical entropy and specific heat, also the corresponding microcanonical quantities, generalizing in this way some results already in the literature for the case n=1. From the expressions that are obtained it is possible to derive the necessary conditions for the equivalence of the canonical and of the microcanonical ensembles. We finally study a simple model, with a two-dimensional order parameter space, in which ensemble inequivalence is realized. [Copyright &y& Elsevier]

Published

2004

24. Ensemble inequivalence: a formal approach

Author

Leyvraz, F. and Ruffo, S.

Subjects

*MATHEMATICAL inequalities, *STATISTICS

Abstract

Ensemble inequivalence has been observed in several systems. In particular, it has been recently shown that negative specific heat can arise in the microcanonical ensemble in the thermodynamic limit for systems with long-range interactions. We display a connection between such behaviour and a mean-field-like structure of the partition function. Since short-range models cannot display this kind of behaviour, this strongly suggests that such systems are necessarily non-mean field in the sense indicated here. We further show that a broad class of systems with non-integrable interactions are indeed of mean-field type in the sense specified, so that they are expected to display ensemble inequivalence as well as the peculiar behaviour described above in the microcanonical ensemble. [Copyright &y& Elsevier]

Published

2002

25. Ensemble inequivalence in the Blume-Emery-Griffiths model near a fourth-order critical point

Author

V. V. Prasad, Stefano Ruffo, David Mukamel, and Alessandro Campa

Subjects

Canonical ensemble, Physics, Statistical Mechanics (cond-mat.stat-mech), Long-range Interactions, Ensemble inequivalence, Theoretical models, FOS: Physical sciences, Ensemble inequivalence, Critical points, Critical points, 01 natural sciences, 010305 fluids & plasmas, Settore FIS/03 - Fisica della Materia, Settore FIS/02 - Fisica Teorica, Modelli e Metodi Matematici, Fourth order, Critical point (thermodynamics), Phase transitions, 0103 physical sciences, Ising model, Condensed Matter::Statistical Mechanics, Microcanonical Ensemble, Statistical physics, 010306 general physics, Mean-Field Model, Condensed Matter - Statistical Mechanics, Phase diagram

Abstract

The canonical phase diagram of the Blume-Emery-Griffiths (BEG) model with infinite-range interactions is known to exhibit a fourth order critical point at some negative value of the bi-quadratic interaction $K, 9 pages, 10 figures

Published

2019

26. Statistical mechanics of systems with long-range interactions and negative absolute temperature

Author

Marco Baldovin, Angelo Vulpiani, and Fabio Miceli

Subjects

Physics, negative temperature, Statistical Mechanics (cond-mat.stat-mech), FOS: Physical sciences, Statistical mechanics, long-range interactions, ensemble inequivalence, Microcanonical ensemble, Molecular dynamics, Phase space, Bounded function, Statistical physics, Negative temperature, Entropy (arrow of time), Absolute zero, Condensed Matter - Statistical Mechanics

Abstract

A Hamiltonian model living in a bounded phase space and with long-range interactions is studied. It is shown, by analytical computations, that there exists an energy interval in which the microcanonical entropy is a decreasing convex function of the total energy, meaning that ensemble equivalence is violated in a negative-temperature regime. The equilibrium properties of the model are then investigated by molecular dynamics simulations: first, the caloric curve is reconstructed for the microcanonical ensemble and compared to the analytical prediction, and a generalized Maxwell-Boltzmann distribution for the momenta is observed; then the nonequivalence between the microcanonical and canonical descriptions is explicitly shown. Moreover, the validity of the Fluctuation-Dissipation Theorem is verified through a numerical study, also at negative temperature and in the region where the two ensembles are nonequivalent.

Published

2019

27. Concavity, Response Functions and Replica Energy

Author

Stefano Ruffo, Lapo Casetti, Agustín Pérez-Madrid, Ivan Latella, Alessandro Campa, and Universitat de Barcelona

Subjects

Particle number, General Physics and Astronomy, FOS: Physical sciences, lcsh:Astrophysics, 01 natural sciences, Article, ensemble inequivalence, 010305 fluids & plasmas, Settore FIS/03 - Fisica della Materia, Additive function, 0103 physical sciences, lcsh:QB460-466, Termodinàmica, Statistical physics, 010306 general physics, lcsh:Science, Mean-Field Model, long-range interactions, Condensed Matter - Statistical Mechanics, Physics, Partition function (statistical mechanics), Statistical Mechanics (cond-mat.stat-mech), Entropy, Concavity, Response functions, Statistical physics, Long-range interactions, Ensemble inequivalence, non-additive systems, Replica, lcsh:QC1-999, Thermodynamic potential, Settore FIS/02 - Fisica Teorica, Modelli e Metodi Matematici, Negative response, non-additive systems, Mecànica estadística, Thermodynamic limit, Microcanonical Ensemble, Thermodynamics, lcsh:Q, Relevant information, Statistical mechanics, lcsh:Physics

Abstract

In nonadditive systems, like small systems or like long-range interacting systems even in the thermodynamic limit, ensemble inequivalence can be related to the occurrence of negative response functions, this in turn being connected with anomalous concavity properties of the thermodynamic potentials associated to the various ensembles. We show how the type and number of negative response functions depend on which of the quantities E, V and N (energy, volume and number of particles) are constrained in the ensemble. In particular, we consider the unconstrained ensemble in which E, V and N fluctuate, physically meaningful only for nonadditive systems. In fact, its partition function is associated to the replica energy, a thermodynamic function that identically vanishes when additivity holds, but that contains relevant information in nonadditive systems., Comment: 22 pages, 2 figures

Published

2018

28. Complete analysis of ensemble inequivalence in the Blume-Emery-Griffiths model

Author

Alessandro Campa, V. V. Hovhannisyan, Nerses Ananikian, and Stefano Ruffo

Subjects

Phase transition, Paramagnetic phasis, Singularity theory, Triple point, Paramagnetic phase, FOS: Physical sciences, 01 natural sciences, Condensed Matter::Disordered Systems and Neural Networks, 010305 fluids & plasmas, Settore FIS/03 - Fisica della Materia, Ensemble inequivalence, Blume-Emery-Griffiths model, Critical point (thermodynamics), 0103 physical sciences, Canonical ensemble, Microcanonical ensembles, Statistical physics, 010306 general physics, Mean-Field Model, Condensed Matter - Statistical Mechanics, Mathematics, Phase diagram, Blume-Emery-Griffiths model, Statistical Mechanics (cond-mat.stat-mech), Long-range Interactions, Ensemble inequivalence, Biquadratic exchange, Settore FIS/02 - Fisica Teorica, Modelli e Metodi Matematici, Microcanonical ensemble, Tricritical point, Second-order phase transition, Microcanonical Ensemble, Condensed Matter::Statistical Mechanics

Abstract

We study inequivalence of canonical and microcanonical ensembles in the mean-field Blume-Emery-Griffiths model. This generalizes previous results obtained for the Blume-Capel model. The phase diagram strongly depends on the value of the biquadratic exchange interaction K, the additional feature present in the Blume-Emery-Griffiths model. At small values of K, as for the Blume-Capel model, lines of first and second order phase transitions between a ferromagnetic and a paramagnetic phase are present, separated by a tricritical point whose location is different in the two ensembles. At higher values of K the phase diagram changes substantially, with the appearance of a triple point in the canonical ensemble which does not find any correspondence in the microcanonical ensemble. Moreover, one of the first order lines that starts from the triple point ends in a critical point, whose position in the phase diagram is different in the two ensembles. This line separates two paramagnetic phases characterized by a different value of the quadrupole moment. These features were not previously studied for other models and substantially enrich the landscape of ensemble inequivalence, identifying new aspects that had been discussed in a classification of phase transitions based on singularity theory. Finally, we discuss ergodicity breaking, which is highlighted by the presence of gaps in the accessible values of magnetization at low energies: it also displays new interesting patterns that are not present in the Blume-Capel model., Comment: Small additions in the Conclusions

Published

2017

29. The world of long-range interactions: A bird’s eye view

Author

Stefano Ruffo and Shamik Gupta

Subjects

Nuclear and High Energy Physics, Field (physics), non-additivity, Physical system, FOS: Physical sciences, Dynamical system, Quasistationary States, 01 natural sciences, 010305 fluids & plasmas, Settore FIS/03 - Fisica della Materia, Ensemble inequivalence, 0103 physical sciences, Coulomb, Statistical physics, 010306 general physics, Condensed Matter - Statistical Mechanics, Spin-½, Physics, Statistical Mechanics (cond-mat.stat-mech), Ergodicity, Relaxation (iterative method), Astronomy and Astrophysics, Statistical mechanics, Nonlinear Sciences - Adaptation and Self-Organizing Systems, Atomic and Molecular Physics, and Optics, quasi-stationary states, Long-range interactions, slow relaxation, Adaptation and Self-Organizing Systems (nlin.AO)

Abstract

In recent years, studies of long-range interacting (LRI) systems have taken centre stage in the arena of statistical mechanics and dynamical system studies, due to new theoretical developments involving tools from as diverse a field as kinetic theory, non-equilibrium statistical mechanics, and large deviation theory, but also due to new and exciting experimental realizations of LRI systems. In this invited contribution, we discuss the general features of long-range interactions, emphasizing in particular the main physical phenomenon of non-additivity, which leads to a plethora of distinct effects, both thermodynamic and dynamic, that are not observed with short-range interactions: Ensemble inequivalence, slow relaxation, broken ergodicity. We also discuss several physical systems with long-range interactions: mean-field spin systems, self-gravitating systems, Euler equations in two dimensions, Coulomb systems, one-component electron plasma, dipolar systems, free-electron lasers, atoms trapped in optical cavities., Invited contribution to a special issue on the occasion of Abdus Salam's 90th birthday; v2: Refs. added

Published

2017

30. Phase transitions in Thirring's model

Author

Ivan Latella, Alessandro Campa, Agustín Pérez-Madrid, Lapo Casetti, and Stefano Ruffo

Subjects

Statistics and Probability, Canonical ensemble, Physics, Phase transition, Statistical Mechanics (cond-mat.stat-mech), Self-gravitating systems, Phase transitions, Ensemble inequivalence, FOS: Physical sciences, Statistical and Nonlinear Physics, Probability and statistics, Kinematics, 01 natural sciences, Critical point (mathematics), 010305 fluids & plasmas, Settore FIS/03 - Fisica della Materia, Microcanonical ensemble, 0103 physical sciences, Homogeneous space, Statistics, Probability and Uncertainty, 010306 general physics, Condensed Matter - Statistical Mechanics, Phase diagram, Mathematical physics

Abstract

In his pioneering work on negative specific heat, Walter Thirring in\-tro\-duced a model that is solvable in the microcanonical ensemble. Here, we give a complete description of the phase-diagram of this model in both the microcanonical and the canonical ensemble, highlighting the main features of ensemble inequivalence. In both ensembles, we find a line of first-order phase transitions which ends in a critical point. However, neither the line nor the point have the same location in the phase-diagram of the two ensembles. We also show that the microcanonical and canonical critical points can be analytically related to each other using a Landau expansion of entropy and free energy, respectively, in analogy with what has been done in [O. Cohen, D. Mukamel, J. Stat. Mech., P12017 (2012)]. Examples of systems with certain symmetries restricting the Landau expansion have been considered in this reference, while no such restrictions are present in Thirring's model. This leads to a phase diagram that can be seen as a prototype for what happens in systems of particles with kinematic degrees of freedom dominated by long-range interactions., 16 pages, 6 figures

Published

2016

31. Dynamics and thermodynamics of rotators interacting with both long- and short-range couplings

Author

David Mukamel, Stefano Ruffo, Alessandro Campa, and Andrea Giansanti

Subjects

Statistics and Probability, Coupling, Physics, Phase transition, Statistical Mechanics (cond-mat.stat-mech), Condensed matter physics, long-range systems, quasi-stationary states, ensemble inequivalence, Relaxation (NMR), FOS: Physical sciences, Statistical mechanics, Condensed Matter Physics, symbols.namesake, Mean field theory, Quantum mechanics, Metastability, symbols, Antiferromagnetism, Hamiltonian (quantum mechanics), Condensed Matter - Statistical Mechanics

Abstract

The effect of nearest-neighbor coupling on the thermodynamic and dynamical properties of the ferromagnetic Hamiltonian Mean Field model (HMF) is studied. For a range of antiferromagnetic nearest-neighbor coupling, a canonical first order transition is observed, and the canonical and microcanonical ensembles are non-equivalent. In studying the relaxation time of non-equilibrium states it is found that as in the HMF model, a class of non-magnetic states is quasi-stationary, with an algebraic divergence of their lifetime with the number of degrees of freedom $N$. The lifetime of metastable states is found to increase exponentially with $N$ as expected., Comment: 12 pages, 6 figures

Published

2006

32. Ensemble inequivalence: a formal approach

Author

Stefano Ruffo and Francois Leyvraz

Subjects

Statistics and Probability, Physics, Partition function (statistical mechanics), Statistical Mechanics (cond-mat.stat-mech), Specific heat, Ensemble inequivalence, FOS: Physical sciences, Long range interactions, Condensed Matter Physics, Settore FIS/03 - Fisica della Materia, Microcanonical ensemble, Thermodynamic limit, Statistical physics, Condensed Matter - Statistical Mechanics

Abstract

Ensemble inequivalence has been observed in several systems. In particular it has been recently shown that negative specific heat can arise in the microcanonical ensemble in the thermodynamic limit for systems with long-range interactions. We display a connection between such behaviour and a mean-field like structure of the partition function. Since short-range models cannot display this kind of behaviour, this strongly suggests that such systems are necessarily non-mean field in the sense indicated here. We further show that a broad class of systems with non-integrable interactions are indeed of mean-field type in the sense specified, so that they are expected to display ensemble inequivalence as well as the peculiar behaviour described above in the microcanonical ensemble., 4 pages, no figures, given at the NEXT2001 conference on non-extensive thermodynamics

Published

2002

33. Ensemble inequivalence in a mean-fieldXYmodel with ferromagnetic and nematic couplings

Author

Fernanda Pereira da Cruz Benetti, Tarcisio Nunes Teles, Arkady Pikovsky, Stefano Ruffo, Shamik Gupta, Yan Levin, Renato Pakter, Department of Physics and Astronomy [Potsdam], Universität Potsdam, Department of Control Theory, Nizhni Novgorod University, Laboratoire de Physique Théorique et Modèles Statistiques (LPTMS), Centre National de la Recherche Scientifique (CNRS)-Université Paris-Sud - Paris 11 (UP11), Instituto de Física (IFUFRGS), Universidade Federal do Rio Grande do Sul [Porto Alegre] (UFRGS), Dipartimento di Fisica e Astronomia [Firenze], and Università degli Studi di Firenze = University of Florence [Firenze] (UNIFI)

Subjects

[PHYS]Physics [physics], Coupling, Physics, Statistical Mechanics (cond-mat.stat-mech), Condensed matter physics, Spins, Ensemble inequivalence, Ferromagnetismo, FOS: Physical sciences, Inverse, Classical XY model, Long-range interactions, Nematic couplings, Ferromagnetism, Mean field theory, Liquid crystal, Diagramas de fase, Quantum mechanics, Condensed Matter - Statistical Mechanics, Phase diagram

Abstract

We explore ensemble inequivalence in long-range interacting systems by studying an XY model of classical spins with ferromagnetic and nematic coupling. We demonstrate the inequivalence by mapping the microcanonical phase diagram onto the canonical one, and also by doing the inverse mapping. We show that the equilibrium phase diagrams within the two ensembles strongly disagree within the regions of first-order transitions, exhibiting interesting features like temperature jumps. In particular, we discuss the coexistence and forbidden regions of different macroscopic states in both the phase diagrams., Comment: 5 pages, 4 figures; v2: published version

Published

2014

34. Ensemble inequivalence in systems with wave-particle interaction

Author

Tarcisio Nunes Teles, Duccio Fanelli, and Stefano Ruffo

Subjects

Canonical ensemble, Physics, Statistical ensemble, Convex entropy, Statistical Mechanics (cond-mat.stat-mech), Isothermal–isobaric ensemble, Ensemble inequivalence, FOS: Physical sciences, Statistical mechanics, Charged particle, Settore FIS/03 - Fisica della Materia, symbols.namesake, Microcanonical ensemble, Wave–particle duality, Wave-particle Hamiltonian, symbols, Statistical physics, Hamiltonian (quantum mechanics), Condensed Matter - Statistical Mechanics

Abstract

The classical wave-particle Hamiltonian is considered in its generalized version, where two modes are assumed to interact with the co-evolving charged particles. The equilibrium statistical mechanics solution of the model is worked out analytically, both in the canonical and the microcanonical ensembles. The competition between the two modes is shown to yield ensemble inequivalence, at variance with the standard scenario where just one wave is allowed to develop. As a consequence, both temperature jumps and negative specific heat can show up in the microcanonical ensemble. The relevance of these findings for both plasma physics and Free Electron Laser applications is discussed., 5 pages, 2 figures

Published

2014

35. Physics of long-range interacting systems

Author

A. Campa, T. Dauxois, D. Fanelli, and S. Ruffo

Subjects

two-dimensional hydrodynamics, Interazioni a lungo raggio, statistical mechanics, mean-field models, ensemble inequivalence, negative specific heat, out-of-equilibrium dynamics, kinetic theory, gravitation, Coulomb, plasma, wave-particles interaction, dipolar, two-dimensional hydrodynamics, meccanica statistica. fenomeno di equilibrio e non equilibrio, ensemble inequivalence, wave-particles interaction, Settore FIS/03 - Fisica della Materia, mean-field models, negative specific heat, gravitation, out-of-equilibrium dynamics, kinetic theory, Coulomb, statistical mechanics, dipolar, plasma

Abstract

This book deals with an important class of many-body systems: those where the interaction potential decays slowly for large inter-particle distance. In particular, systems where the decay is slower than the inverse inter-particle distance raised to the dimension of the embedding space. Gravitational and Coulomb interactions are the most prominent examples. However, it has become clear that long-range interactions are more common than previously thought. This has stimulated a growing interest in the study of long-range interacting systems, which has led to a much better understanding of the many peculiarities in their behaviour. The seed of all particular features of these systems, both at equilibrium and out-of-equilibrium, is the lack of additivity. It is now well understood that this does not prevent a statistical mechanics treatment. However, it does require a more in-depth study of the thermodynamic limit and of all related theoretical concepts. A satisfactory understanding of properties generally considered as oddities only a couple of decades ago has now been reached: ensemble inequivalence, negative specific heat, negative susceptibility, ergodicity breaking, out-of-equilibrium quasi-stationary-states, anomalous diffusion, etc. The first two parts describe the theoretical and computational instruments needed for addressing the study of both equilibrium and dynamical properties of systems subject to long-range forces. The third part of the book is devoted to discussing the applications of such techniques to the most relevant examples of long-range systems. The only prerequisite is a basic course in statistical mechanics.

Published

2014

36. Large deviations techniques for long-range interactions

Author

Aurelio Patelli and Stefano Ruffo

Subjects

Canonical ensemble, Physics, Ergodicity, Ensemble inequivalence, Quasistationary states, Classical XY model, Settore FIS/03 - Fisica della Materia, Microcanonical ensemble, Long-range interactions, Variational method, Large deviations theory, Statistical physics, Entropy (arrow of time), Potts model

Abstract

After a brief introduction to the main equilibrium features of long-range interacting systems (ensemble inequivalence, negative specific heat and susceptibility, broken ergodicity, etc.) and a recall of Cramer’s theorem, we discuss in this chapter a general method which allows us to compute microcanonical entropy for systems of the mean-field type. The method consists in expressing the Hamiltonian in terms of global variables and, then, in computing the phase-space volume by fixing a value for these variables: this is done by using large deviations. The calculation of entropy as a function of energy is, thus, reformulated as the solution of a variational problem. We show the power of the method by explicitly deriving the equilibrium thermodynamic properties of the three-state Potts model, the Blume-Capel model, an XY spin system, the ϕ 4 model and the Colson-Bonifacio model of the free electron laser. When short range interactions coexist with long-range ones, the method cannot be straightforwardly applied. We discuss an alternative variational method which allows us to solve the XY model with both mean-field and nearest neighbor interactions.

Published

2014

37. Concavity, Response Functions and Replica Energy.

Author

Campa, Alessandro, Casetti, Lapo, Latella, Ivan, Pérez-Madrid, Agustín, and Ruffo, Stefano

Subjects

*INFORMATION retrieval, *THERMODYNAMICS, *ENTROPY, *FUZZY measure theory, *ENERGY function

Abstract

In nonadditive systems, like small systems or like long-range interacting systems even in the thermodynamic limit, ensemble inequivalence can be related to the occurrence of negative response functions, this in turn being connected with anomalous concavity properties of the thermodynamic potentials associated with the various ensembles. We show how the type and number of negative response functions depend on which of the quantities E, V and N (energy, volume and number of particles) are constrained in the ensemble. In particular, we consider the unconstrained ensemble in which E, V and N fluctuate, which is physically meaningful only for nonadditive systems. In fact, its partition function is associated with the replica energy, a thermodynamic function that identically vanishes when additivity holds, but that contains relevant information in nonadditive systems. [ABSTRACT FROM AUTHOR]

Published

2018

38. Statistical mechanics and dynamics of long-range interacting systems

Author

Aurelio, Patelli and Ruffo, Stefano

Subjects

Long-range interactions, Ensemble inequivalence, Quasistationary states

Published

2013

39. Mélange et circulation océanique : une approche par la physique statistique

Author

Venaille, Antoine, Institut Non Linéaire de Nice Sophia-Antipolis (INLN), Université Nice Sophia Antipolis (... - 2019) (UNS), COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-Centre National de la Recherche Scientifique (CNRS), Laboratoire des Écoulements Géophysiques et Industriels [Grenoble] (LEGI), Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Centre National de la Recherche Scientifique (CNRS)-Université Joseph Fourier - Grenoble 1 (UJF), Université Joseph-Fourier - Grenoble I, Joël Sommeria(sommeria@coriolis-legi.org), and anr statflow

Subjects

jets, mélange, [PHYS]Physics [physics], [SDU.OCEAN]Sciences of the Universe [physics]/Ocean, Atmosphere, turbulence, stability, systèmes à interactions à longue portée, long range interacting systems, inéquivalence d'ensemble, ensemble inequivalence, Fofonoff flows, stratified flows, fluides stratifiés, mécanique statistique, écoulements de Fofonoff, mixing, stabilité, Statistical mechanics

Abstract

Understanding how the small scales affect the large scales in oceans is an important issue for the description of surface currents and of the vertical structure of the oceans. The huge number of degrees of freedom involved in those problems makes any deterministic approach illusory. By contrast, the traditional tools of statistical mechanics allow to reduce those problems to the study of only a few parameters. In the first part, the equilibrium statistical mechanics of two-dimensional flows is applied to the study of simple ocean models. The second part is a phenomenological approach to turbulent mixing in stratified flows; the aim is to describe the temporal evolution of the probability to measure a certain value of the fluid density at a given depth.; La compréhension de l'effet des petites échelles turbulentes sur l'organisation des grandes échelles des écoulements océaniques est un problème important, tant pour la description des courants de surface que pour la structure verticale des océans. Ces écoulements sont caractérisés par un nombre de degrés de liberté très élevé qui rend illusoire toute approche déterministe. Les outils de mécanique statistique permettent en revanche de réduire ces problèmes à l'étude de quelques paramètres. Dans la première partie, nous appliquons la mécanique statistique d'équilibre des écoulements bidimensionnels à l'étude de modèles simples d'océan. Il s'agit de comprendre les phénomènes d'organisation des courants à grande échelle. La seconde partie est une approche phénoménologique du mélange turbulent dans les fluides stratifiés. Il s'agit de décrire l'évolution temporelle de la probabilité de mesurer une certaine densité de fluide à une profondeur donnée.

Published

2008

40. Negative magnetic susceptibility and nonequivalent ensembles for the mean-field phi(4) spin model

Author

Campa, A., Ruffo, S., and Touchette, H.

Subjects

mean-field models, nonconcave entropies, Condensed Matter - Statistical Mechanics, ensemble inequivalence, Settore FIS/03 - Fisica della Materia

Abstract

We calculate the thermodynamic entropy of the mean-field $\phi^4$ spin model in the microcanonical ensemble as a function of the energy and magnetization of the model. The entropy and its derivative are obtained from the theory of large deviations, as well as from Rugh's microcanonical formalism, which is implemented by computing averages of suitable observables in microcanonical molecular dynamics simulations. Our main finding is that the entropy is a concave function of the energy for all values of the magnetization, but is nonconcave as a function of the magnetization for some values of the energy. This last property implies that the magnetic susceptibility of the model can be negative when calculated microcanonically for fixed values of the energy and magnetization. This provides a magnetization analog of negative heat capacities, which are well-known to be associated in general with the nonequivalence of the microcanonical and canonical ensembles. Here, the two ensembles that are nonequivalent are the microcanonical ensemble in which the energy and magnetization are held fixed and the canonical ensemble in which the energy and magnetization are fixed only on average by fixing the temperature and magnetic field., Comment: 14 pages, 4 figures, 2 appendices, REVTeX4

Published

2007

41. Dinámica y termodinámica de sistemas no extensivos

Author

Ison, Matías Julián and Dorso, Claudio O.

Subjects

COLISIONES DE NUCLEOS PESADOS, PHASE TRANSITIONS, HEAVY ION COLLISIONS, FRAGMENTACION, DINAMICA MOLECULAR, ENSEMBLE INEQUIVALENCE, TRANSICIONES DE FASE, INEQUIVALENCIA DE ENSAMBLES, SISTEMAS NO EXTENSIVOS, FISICA COMPUTACIONAL, MOLECULAR DYNAMICS, NON-EXTENSIVE SYSTEMS, FRAGMENTATION, COMPUTATIONAL PHYSICS

Abstract

Esta tesis presenta un estudio de la mecánica estadística de sistemas no extensivos. En particular trataremos en forma abarcativa el proceso de fragmentación de sistemas clásicos que interactúan mediante diversos potenciales, de corto y largo rango, sujetos a condiciones de contorno significativamente diferentes mediante técnicas de Dinámica Molecular. El uso de potenciales que connan al sistema permite el estudio de aspectos generales de la termodinámica de sistemas en equilibrio lejos del límite termodinámico. Mediante la utilización de condiciones de contorno abiertas, que dejan al sistema evolucionar en el vacío, analizamos varios aspectos relacionados con la falta de equilibrio en el mismo. Los resultados presentados apuntan a contribuir al entendimiento de los fundamentos de la mecánica estadística y a proveer un marco referencial de particular interés para el problema de multifragmentacion nuclear y por extensión a la física de agregados que evaporan. En relación a los sistemas nitos diluidos en equilibrio mostramos evidencias de una transición de fase de primer orden entre un estado tipo líquido, donde el sistema forma una gran gota, a un estado tipo gaseoso, donde el sistema se encuentra formado por fragmentos livianos y partículas libres. Identificamos el origen de comportamientos anómalos desde el punto de vista de la mecánica estadística usual: calores específicos negativos e intrusos convexos en la entropía microcanónica, signaturas de la transición de fase en los sistemas finitos. En particular mostramos que, contrariamente a lo que se creía anteriormente, la aparición de capacidades caloríficas negativas no se debe a la presencia de interacciones de largo rango ni a metaestabilidades, sino a la generación de superficies internas en el espacio configuracional. El análisis de sistemas que evolucionan libremente nos permitió confirmar que estos alcanzan cierto grado de equilibrio local alrededor de un modo colectivo de expansión. Esto hizo posible proponer termómetros que dieron lugar a la confirmación de que la temperatura del sistema alcanza una meseta para altas energías, resultado particularmente relevante en el campo de las colisiones nucleares a energías intermedias. Otros resultados novedosos que se presentan en esta tesis incluyen haber encontrado la presencia y la vinculación existente entre las uctuaciones anormalmente grandes de la energía cinética del sistema y la distribución de masas asintóticas, y el análisis del problema de la reducibilidad en la fragmentación de sistemas clásicos This thesis presents a statistical mechanics study of non-extensive systems. In particular, we present an in-depth study of the fragmentation process of classical systems interacting via diverse potentials,both short and long-ranged, under significantly different boundary conditions, by means of Molecular Dynamics techniques. With the utilization of conning potentials a study of general aspects of the thermodynamics of systems at equilibrium far away from the thermodynamic limit is performed. Open boundary conditions, which let the system freely expand in vacuum, allow an exploration of the nonequilibrium features of the process. Our goal in this thesis is to contribute to the understanding of the fundamentals of statistical mechanics on one hand, and on the other hand to provide a general framework of particular interest to the nuclear multifragmentation problem and by extension to the melting of atomic clusters. Concerning equilibrated nite systems we present evidences of a first order phase transition between a liquid-like state, where the system behaves as a big drop, to a vapour-like state, where the system is composed by light clusters and free particles. We identified the origin of anomalous behaviors from the point of view of standard statistical mechanics, like negative heat capacities and convex intruders in the microcanonical entropy, signatures of a phase transition in nite systems. In particular we show that, contrary to previous belief, their appearance are not due to the presence of long-range interactions neither to metastabilities but to the development of internal surfaces in configuration space. By studying systems freely evolving in vacuum we confirmed that a certain degree of equilibration around an expanding collective motion is reached. This fact allowed us to propose several thermometers which let us confirm that temperature reaches a plateau at high energies, a particularly relevant result for the eld of nuclear collisions at intermediate energies. Other new results that are original to this thesis include the ending of anomalous big uctuations of the kinetic energy of the system and its relationship with asymptotic mass distributions, and the analysis of a classical fragmenting systems in terms of reducibility. Fil: Ison, Matías Julián. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina.

Published

2006