论文信息 - Noise-induced multistability in chemical systems: Discrete versus continuum modeling.

Noise-induced multistability in chemical systems: Discrete versus continuum modeling.

The noisy dynamics of chemical systems is commonly studied using either the chemical master equation (CME) or the chemical Fokker-Planck equation (CFPE). The latter is a continuum approximation of the discrete CME approach. It has recently been shown that for a particular system, the CFPE captures noise-induced multistability predicted by the CME. This phenomenon involves the CME's marginal probability distribution changing from unimodal to multimodal as the system size decreases below a critical value. We here show that the CFPE does not always capture noise-induced multistability. In particular we find simple chemical systems for which the CME predicts noise-induced multistability, whereas the CFPE predicts monostability for all system sizes.

A. Duncan | S. Liao | T. Vejchodský | R. Erban | R. Grima

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