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Exhaustive study of the noise-induced phase transition in a stochastic model of self-catalyzed reactions
T. M. Pham, Yu. P. Virchenko National Research University "Belgorod State University", Belgorod, Russia
Abstract:
We completely investigate the stationary distribution density in the space of relative concentrations for the three-parameter stochastic Horsthemke–Lefever model of a binary self-catalyzed cyclic chemical reaction with perturbations produced by thermal fluctuations of reagents taken into account. This model is a stationary diffusion random process generated by a stochastic equation with the Stratonovich differential, whose marginal distribution density admits a bifurcation restructuring from the unimodal to the bimodal phase with increasing noise intensity, which is interpreted physically as a dynamical phase transition induced by fluctuations in the system.
Keywords:
bimodal distribution, bifurcation, critical surface, stoichiometric coefficient, stochastic differential equation, diffusion Markov process, Fokker–Planck equation, chemical kinetics equation, phase diagram, noise-induced phase transition, fluctuationbimodal distribution, bifurcation, critical surface, stoichiometric coefficient, stochastic differential equation, diffusion Markov process, Fokker–Planck equation, chemical kinetics equation, phase diagram, noise-induced phase transition, fluctuation.
Received: 03.11.2015 Revised: 22.11.2015
Citation:
T. M. Pham, Yu. P. Virchenko, “Exhaustive study of the noise-induced phase transition in a stochastic model of self-catalyzed reactions”, TMF, 188:2 (2016), 318–336; Theoret. and Math. Phys., 188:2 (2016), 1236–1252
Linking options:
https://www.mathnet.ru/eng/tmf9094https://doi.org/10.4213/tmf9094 https://www.mathnet.ru/eng/tmf/v188/i2/p318
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