{ "id": "cond-mat/0302032", "version": "v11", "published": "2003-02-03T13:15:45.000Z", "updated": "2015-02-19T19:05:30.000Z", "title": "On the objective origin of the phase transitions and metastability in many-particle systems", "authors": [ "A. G. Godizov", "A. A. Godizov" ], "comment": "16 pages + Appendix has been added; minor corrections in the main text", "journal": "Int. J. Mod. Phys. B 28 (2014) 1450163", "doi": "10.1142/S021797921450163X", "categories": [ "cond-mat.stat-mech", "cond-mat.mtrl-sci", "cond-mat.soft", "physics.chem-ph", "quant-ph" ], "abstract": "Equilibrium statistical mechanics is intended to link the microscopic dynamics of particles to the thermodynamic laws for macroscopic quantities. However, the modern statistical theory is faced with significant difficulties, as applied to description of the macroscopic properties of real condensed media within wide thermodynamic ranges, including the vicinities of the phase transition points. A particular problem is the absence of metastable states in the Gibbs statistical mechanics of the systems composed of finite number of particles. Nevertheless, accordance between equilibrium statistical mechanics and thermodynamics of condensed media is achievable if to take account of the mutual correlation (the feedback) between the microscopic properties of molecules and the macrostate of the corresponding medium. This can be done via usage of the \"enhanced\" Hamilton operator of the considered many-particle system, which contains some temperature-dependent term(s), and the following introduction of the generalized equilibrium distribution over microstates. For illustration of the reasonableness of the proposed approach (and of its practical availability in the applications for the computation of the macroscopic characteristics of condensed media), a cell model of melting/crystallization and metastable supercooled liquid for a water-like medium is presented.", "revisions": [ { "version": "v10", "updated": "2014-04-16T18:45:20.000Z", "abstract": "The modern equilibrium statistical mechanics (intended to link microscopic dynamics to thermodynamic laws for macroscopic quantities) are faced with significant difficulties, as applied to description of the macroscopic properties of real condensed media within wide thermodynamic ranges, including the vicinities of the phase transition points. A particular problem is the absence of metastable states in the Gibbs statistical mechanics of the systems composed of finite number of particles. Nevertheless, accordance between equilibrium statistical mechanics and thermodynamics of condensed media is achievable if to take account of the mutual correlation (the feedback) between the microscopic properties of molecules and the macrostate of the corresponding medium. This can be done via usage of the \"enhanced\" Hamilton operator of the considered many-particle system, which contains some temperature-dependent term(s), and the following introduction of the generalized equilibrium distribution over microstates. For illustration of the reasonableness of the proposed approach (and of its practical availability in the applications to computing the macroscopic characteristics of condensed media), a cell model of melting/crystallization and metastable supercooled liquid for a water-like medium is presented.", "comment": "16 pages, minor corrections" }, { "version": "v11", "updated": "2015-02-19T19:05:30.000Z" } ], "analyses": { "subjects": [ "64.60.My", "64.60.Bd", "05.70.Fh", "64.70.dm", "64.70.D-" ], "keywords": [ "many-particle system", "objective origin", "equilibrium statistical mechanics", "metastability", "wide thermodynamic ranges" ], "tags": [ "journal article" ], "publication": { "journal": "International Journal of Modern Physics B", "year": 2014, "month": "Jun", "volume": 28, "number": 24, "pages": 1450163 }, "note": { "typesetting": "TeX", "pages": 16, "language": "en", "license": "arXiv", "status": "editable", "adsabs": "2014IJMPB..2850163G" } } }