Search results for "Canonical ensemble"

showing 8 items of 58 documents

A Stochastic Approach to Quantum Statistics Distributions: Theoretical Derivation and Monte Carlo Modelling

2009

Abstract. We present a method aimed at a stochastic derivation of the equilibrium distribution of a classical/quantum ideal gas in the framework of the canonical ensemble. The time evolution of these ideal systems is modelled as a series of transitions from one system microstate to another one and thermal equilibrium is reached via a random walk in the single-particle state space. We look at this dynamic process as a Markov chain satisfying the condition of detailed balance and propose a variant of the Monte Carlo Metropolis algorithm able to take into account indistinguishability of identical quantum particles. Simulations performed on different two-dimensional (2D) systems are revealed to…

Statistics and ProbabilityCanonical ensemblePhysicsclassical Monte Carlo simulations quantum Monte Carlo simulations stochastic particle dynamics (theory)Monte Carlo methodStatistical and Nonlinear PhysicsMarkov chain Monte CarloIdeal gasMicrostate (statistical mechanics)symbols.namesakeThermodynamic limitDynamic Monte Carlo methodsymbolsStatistical physicsStatistics Probability and UncertaintyQuantum statistical mechanics
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Microcanonical foundation of nonextensivity and generalized thermostatistics based on the fractality of the phase space

2005

We develop a generalized theory of (meta)equilibrium statistical mechanics in the thermodynamic limit valid for both smooth and fractal phase spaces. In the former case, our approach leads naturally to Boltzmann-Gibbs standard thermostatistics while, in the latter, Tsallis thermostatistics is straightforwardly obtained as the most appropriate formalism. We first focus on the microcanonical ensemble stressing the importance of the limit $t \to \infty$ on the form of the microcanonical measure. Interestingly, this approach leads to interpret the entropic index $q$ as the box-counting dimension of the (microcanonical) phase space when fractality is considered.

Statistics and ProbabilityPhysicsStatistical Mechanics (cond-mat.stat-mech)Thermodynamic betaFOS: Physical sciencesStatistical mechanicsCondensed Matter PhysicsFormalism (philosophy of mathematics)Microcanonical ensembleFractalPhase spaceThermodynamic limitCondensed Matter::Statistical MechanicsStatistical physicsCondensed Matter - Statistical MechanicsPhysica A: Statistical Mechanics and its Applications
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Microcanonical Determination of the Interface Tension of Flat and Curved Interfaces from Monte Carlo Simulations

2012

The investigation of phase coexistence in systems with multi-component order parameters in finite systems is discussed, and as a generic example, Monte Carlo simulations of the two-dimensional q-state Potts model (q=30) on LxL square lattices (40<=L<=100) are presented. It is shown that the microcanonical ensemble is well-suited both to find the precise location of the first order phase transition and to obtain an accurate estimate for the interfacial free energy between coexisting ordered and disordered phases. For this purpose, a microcanonical version of the heatbath algorithm is implemented. The finite size behaviour of the loop in the curve describing the inverse temperature vers…

Thermal equilibriumPhysicsPhase transitionSpinodalStatistical Mechanics (cond-mat.stat-mech)CondensationMonte Carlo methodFOS: Physical sciencesCondensed Matter Physics01 natural sciences010305 fluids & plasmasMicrocanonical ensemblePhase (matter)0103 physical sciencesGeneral Materials ScienceStatistical physics010306 general physicsCondensed Matter - Statistical MechanicsPotts model
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Grand-canonical approach to density functional theory of electrocatalytic systems: Thermodynamics of solid-liquid interfaces at constant ion and elec…

2018

Properties of solid-liquid interfaces are of immense importance for electrocatalytic and electrochemical systems, but modeling such interfaces at the atomic level presents a serious challenge and approaches beyond standard methodologies are needed. An atomistic computational scheme needs to treat at least part of the system quantum mechanically to describe adsorption and reactions, while the entire system is in thermal equilibrium. The experimentally relevant macroscopic control variables are temperature, electrode potential, and the choice of the solvent and ions, and these need to be explicitly included in the computational model as well; this calls for a thermodynamic ensemble with fixed…

Work (thermodynamics)Materials scienceImplicit solvationGeneral Physics and AstronomyElectronDielectric010402 general chemistry01 natural sciencesELECTROCHEMISTRYthermodynamicsCHEMISTRY0103 physical sciencesWATERsolid-liquid interfacesStatistical physicsPhysical and Theoretical Chemistryrajapintailmiötta116QuantumAB-INITIOThermal equilibriumSELF-CONSISTENTta114010304 chemical physicstiheysfunktionaaliteoriaSIMULATIONS0104 chemical sciencesGrand canonical ensembleREDUCTIONCONTINUUMSOLVATIONSolvent modelsStandard electrode potentialtermodynamiikkakatalyysiDensity functional theoryElectronic densityAPPROXIMATIONElectrode potential
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Numerical Evidences of Polarization Switching in PMN Type Relaxor Ferroelectrics

2011

We present a conceptual and computational framework for chemically ordered Pb(Mg 1/3 Nb 2/3 O 3) (PMN) type supercells violating disorder of the host lattice. The effective Hamiltonian is specified by invariance under permutations of supercells and by the dipole-dipole interaction supporting both local nonzero and zero mean polarization of the structure. Statistics treated in canonical ensemble within the mean field approach reveals emergence of polar nanoregions as supported by interplay between the (random) initial state polarization of supercells and their interactions increased at cooling.

Zero meanCanonical ensemblePhysicsCondensed matter physicsCondensed Matter PhysicsPolarization (waves)Electronic Optical and Magnetic MaterialsCondensed Matter::Materials Sciencesymbols.namesakeMean field theoryControl and Systems EngineeringLattice (order)Materials ChemistryCeramics and CompositessymbolsPolarElectrical and Electronic EngineeringHamiltonian (quantum mechanics)Integrated Ferroelectrics
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Unmixing of Polymer Blends Confined in Ultrathin Films:  Crossover between Two-Dimensional and Three-Dimensional Behavior

2006

The interplay between chain conformations and phase separation in binary symmetric polymer mixtures confined into thin films by "neutral" hard walls (i.e., walls that do not preferentially attract or repel one of the two components of the mixture) is studied by Monte Carlo simulations. Using the bond fluctuation model on a simple cubic lattice in the semi grand canonical ensemble, we locate the critical temperature of demixing via finite size scaling methods for a wide range of chain lengths (16/= N/= 256 effective monomers per chain) and film thicknesses (2/= D/= 19 lattice spacings). Simultaneously, we investigate the geometrical structure of the chains, showing that despite using melt de…

chemistry.chemical_classificationMaterials scienceCondensed matter physicsMonte Carlo methodPolymerSurfaces Coatings and FilmsGrand canonical ensemblechemistryLattice (order)Materials ChemistryPerpendicularRadius of gyrationPolymer blendPhysical and Theoretical ChemistryScalingThe Journal of Physical Chemistry B
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Coil-bridge transition in a single polymer chain as an unconventional phase transition: theory and simulation.

2014

The coil-bridge transition in a self-avoiding lattice chain with one end fixed at height H above the attractive planar surface is investigated by theory and Monte Carlo simulation. We focus on the details of the first-order phase transition between the coil state at large height H ⩾ Htr and a bridge state at H ⩽ Htr, where Htr corresponds to the coil-bridge transition point. The equilibrium properties of the chain were calculated using the Monte Carlo pruned-enriched Rosenbluth method in the moderate adsorption regime at (H/Na)tr ⩽ 0.27 where N is the number of monomer units of linear size a. An analytical theory of the coil-bridge transition for lattice chains with excluded volume interact…

chemistry.chemical_classificationPhase transitionCondensed matter physicsChemistryPolymersMonte Carlo methodGeneral Physics and AstronomyThermodynamicsPolymerPhase TransitionMicrocanonical ensemblePlanarTransition pointEnergy TransferLattice (order)Excluded volumeThermodynamicsAdsorptionPhysical and Theoretical ChemistryMonte Carlo MethodThe Journal of chemical physics
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Constant inner potential DFT for modelling electrochemical systems under constant potential and bias

2021

Electrochemical interfaces and reactions play a decisive role in e.g. clean energy conversion but understanding their complex chemistry remains an outstanding challenge. Constant potential or grand canonical ensemble (GCE) simulations are indispensable for unraveling the properties of electrochemical processes as a function of the electrode potential. Currently, constant electrode potential calculations at the density functional theory (DFT) level are carried out by fixing the Fermi level of the simulation cell. However, the Fermi level from DFT calculations does does not always reflect the experimentally controlled electrode potential or describe the thermodynamic independent variable in G…

symbols.namesakeGrand canonical ensembleMaterials scienceChemical physicsFermi levelsymbolsDensity functional theoryConstant (mathematics)ElectrocatalystForce field (chemistry)Electrode potentialElectrochemical potential
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