An introduction to Monte Carlo methods

Publication date

2015-01-15

Authors

Walter, J. -C.
Barkema, G.T.ORCID 0000-0001-5289-4147ISNI 0000000117189768

Editors

Advisors

Supervisors

Document Type

Article
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License

taverne

Abstract

Monte Carlo simulations are methods for simulating statistical systems. The aim is to generate a representative ensemble of configurations to access thermodynamical quantities without the need to solve the system analytically or to perform an exact enumeration. The main principles of Monte Carlo simulations are ergodicity and detailed balance. The Ising model is a lattice spin system with nearest neighbor interactions that is appropriate to illustrate different examples of Monte Carlo simulations. It displays a second order phase transition between disordered (high temperature) and ordered (low temperature) phases, leading to different strategies of simulations. The Metropolis algorithm and the Glauber dynamics are efficient at high temperature. Close to the critical temperature, where the spins display long range correlations, cluster algorithms are more efficient. We introduce the rejection free (or continuous time) algorithm and describe in details an interesting alternative representation of the Ising model using graphs instead of spins with the so-called Worm algorithm. We conclude with an important discussion of the dynamical effects such as thermalization and correlation time. (C) 2014 Elsevier B.V. All rights reserved.

Keywords

Monte Carlo simulations, Ising model, Algorithms, COUPLED CHEMICAL-REACTIONS, SPIN SYSTEMS, ISING-MODEL, SIMULATION, ALGORITHM, Taverne

Citation

Walter, J -C & Barkema, G T 2015, 'An introduction to Monte Carlo methods', Physica. A, theoretical and statistical physics, vol. 418, pp. 78-87. https://doi.org/10.1016/j.physa.2014.06.014