Disorder and Critical Phenomena Through Basic Probability Models
Giacomin, Giambattista.
Disorder and Critical Phenomena Through Basic Probability Models École d’Été de Probabilités de Saint-Flour XL – 2010 / [electronic resource] : by Giambattista Giacomin. - XI, 130 p. 12 illus. online resource. - École d'Été de Probabilités de Saint-Flour, 2025 0721-5363 ; . - École d'Été de Probabilités de Saint-Flour, 2025 .
1 Introduction -- 2 Homogeneous pinning systems: a class of exactly solved models -- 3 Introduction to disordered pinning models -- 4 Irrelevant disorder estimates -- 5 Relevant disorder estimates: the smoothing phenomenon -- 6 Critical point shift: the fractional moment method -- 7 The coarse graining procedure -- 8 Path properties.
Understanding the effect of disorder on critical phenomena is a central issue in statistical mechanics. In probabilistic terms: what happens if we perturb a system exhibiting a phase transition by introducing a random environment? The physics community has approached this very broad question by aiming at general criteria that tell whether or not the addition of disorder changes the critical properties of a model: some of the predictions are truly striking and mathematically challenging. We approach this domain of ideas by focusing on a specific class of models, the "pinning models," for which a series of recent mathematical works has essentially put all the main predictions of the physics community on firm footing; in some cases, mathematicians have even gone beyond, settling a number of controversial issues. But the purpose of these notes, beyond treating the pinning models in full detail, is also to convey the gist, or at least the flavor, of the "overall picture," which is, in many respects, unfamiliar territory for mathematicians.
9783642211560
10.1007/978-3-642-21156-0 doi
Distribution (Probability theory.
Mathematics.
Mathematical physics.
Statistical physics.
Probability Theory and Stochastic Processes.
Applications of Mathematics.
Complex Systems.
Mathematical Methods in Physics.
Statistical Physics and Dynamical Systems.
QA273.A1-274.9 QA274-274.9
519.2
Disorder and Critical Phenomena Through Basic Probability Models École d’Été de Probabilités de Saint-Flour XL – 2010 / [electronic resource] : by Giambattista Giacomin. - XI, 130 p. 12 illus. online resource. - École d'Été de Probabilités de Saint-Flour, 2025 0721-5363 ; . - École d'Été de Probabilités de Saint-Flour, 2025 .
1 Introduction -- 2 Homogeneous pinning systems: a class of exactly solved models -- 3 Introduction to disordered pinning models -- 4 Irrelevant disorder estimates -- 5 Relevant disorder estimates: the smoothing phenomenon -- 6 Critical point shift: the fractional moment method -- 7 The coarse graining procedure -- 8 Path properties.
Understanding the effect of disorder on critical phenomena is a central issue in statistical mechanics. In probabilistic terms: what happens if we perturb a system exhibiting a phase transition by introducing a random environment? The physics community has approached this very broad question by aiming at general criteria that tell whether or not the addition of disorder changes the critical properties of a model: some of the predictions are truly striking and mathematically challenging. We approach this domain of ideas by focusing on a specific class of models, the "pinning models," for which a series of recent mathematical works has essentially put all the main predictions of the physics community on firm footing; in some cases, mathematicians have even gone beyond, settling a number of controversial issues. But the purpose of these notes, beyond treating the pinning models in full detail, is also to convey the gist, or at least the flavor, of the "overall picture," which is, in many respects, unfamiliar territory for mathematicians.
9783642211560
10.1007/978-3-642-21156-0 doi
Distribution (Probability theory.
Mathematics.
Mathematical physics.
Statistical physics.
Probability Theory and Stochastic Processes.
Applications of Mathematics.
Complex Systems.
Mathematical Methods in Physics.
Statistical Physics and Dynamical Systems.
QA273.A1-274.9 QA274-274.9
519.2