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Correlations in stochastic theories of chemical reactions

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Abstract

A comprehensive study of correlations in linear and nonlinear chemical reactions is presented using coupled chemical and diffusion master equations. As a consequence of including correlations in linear reactions the approach to the steady-state Poisson distribution from an initial non-Poissonian distribution is given by a power law rather than the exponential predicted by neglecting correlations. In nonlinear reactions we show that a steadystate Poisson distribution is achieved in small volumes, whereas in large volumes a non-Poissonian distribution is built up via the correlation. The spatial correlation function is calculated for two examples, one which exhibits an instability, the other which exhibits a second-order phase transition, and correlation length and correlation time are calculated and shown to become infinite as the critical point is approached. The critical exponents are found to be classical.

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Authors and Affiliations

  1. Physics Department, University of Waikato, Hamilton, New Zealand

    C. W. Gardiner, K. J. McNeil, D. F. Walls & I. S. Matheson

Authors
  1. C. W. Gardiner
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  2. K. J. McNeil
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  3. D. F. Walls
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  4. I. S. Matheson
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Gardiner, C.W., McNeil, K.J., Walls, D.F. et al. Correlations in stochastic theories of chemical reactions. J Stat Phys 14, 307–331 (1976). https://doi.org/10.1007/BF01030197

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  • DOI: https://doi.org/10.1007/BF01030197

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