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RESEARCH PRODUCT
MONTE CARLO METHODS FOR FIRST ORDER PHASE TRANSITIONS: SOME RECENT PROGRESS
David P. LandauKurt BinderHans-peter DeutschJ. D. RegerM. ScheucherKatharina Vollmayrsubject
Phase transitionMonte Carlo methodGeneral Physics and AstronomyThermodynamic integrationStatistical and Nonlinear PhysicsParameter spaceCritical point (mathematics)Computer Science ApplicationsComputational Theory and MathematicsWetting transitionStatistical physicsScalingMathematical PhysicsMathematicsPotts modeldescription
This brief review discusses methods to locate and characterize first order phase transitions, paying particular attention to finite size effects. In the first part, the order parameter probability distribution and its fourth-order cumulant is discussed for thermally driven first-order transitions (the 3-state Potts model in d=3 dimensions is treated as an example). First-order transitions are characterized by a minimum of the cumulant, which gets very deep for large enough systems. In the second part, we discuss how to locate first order phase boundaries ending in a critical point in a large parameter space. As an example, the study of the unmixing transition of asymmetric polymer mixtures by a combination of histogram techniques and finite size scaling is described. As a final problem, we discuss the shift of the gas-liquid condensation in thin-film geometry confined between two parallel plates due to boundary fields (“capillary condensation”). Being interested in temperatures far below bulk criticality (e. g. near the wetting transition), special thermodynamic integration techniques are the method of choice, rather than the use of finite sizes scaling to map out the (asymmetric) phase diagram.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 1992-10-01 | International Journal of Modern Physics C |