Non-equilibrium dynamics of reaction-diffusion systems

Fluctuations are known to radically alter the behaviour of reaction-diffusion systems. Below a certain upper critical dimension d<sub>c</sub> , this effect results in the breakdown of traditional approaches, such as mean field rate equations. In this thesis we tackle this fluctuation pro...

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Main Author: Howard, Martin
Published: University of Oxford 1996
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Online Access:http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.318754
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spelling ndltd-bl.uk-oai-ethos.bl.uk-3187542015-03-19T05:18:32ZNon-equilibrium dynamics of reaction-diffusion systemsHoward, Martin1996Fluctuations are known to radically alter the behaviour of reaction-diffusion systems. Below a certain upper critical dimension d<sub>c</sub> , this effect results in the breakdown of traditional approaches, such as mean field rate equations. In this thesis we tackle this fluctuation problem by employing systematic field theoretic/renormalisation group methods, which enable perturbative calculations to be made below d<sub>c</sub>. We first consider a steady state reaction front formed in the two species irreversible reaction A + B → Ø. In one dimension we demonstrate that there are two components to the front - one an intrinsic width, and one caused by the ability of the centre of the front to wander. We make theoretical predictions for the shapes of these components, which are found to be in good agreement with our one dimensional simulations. In higher dimensions, where the intrinsic component dominates, we also make calculations for its asymptotic profile. Furthermore, fluctuation effects lead to a prediction of asymptotic power law tails in the intrinsic front in all dimensions. This effect causes high enough order spatial moments of a time dependent reaction front to exhibit multiscaling. The second system we consider is a time dependent multispecies reaction-diffusion system with three competing reactions A+A → Ø, B + B → Ø, and A + B → Ø, starting with homogeneous initial conditions. Using our field theoretic formalism we calculate the asymptotic density decay rates for the two species for d ≤ d<sub>c</sub>. These calculations are compared with other approximate methods, such as the Smoluchowski approach, and also with previous simulations and exact results.530.1Reaction-diffusion equationsUniversity of Oxfordhttp://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.318754http://ora.ox.ac.uk/objects/uuid:4485a178-6262-4487-b40f-7c7ec790d687Electronic Thesis or Dissertation
collection NDLTD
sources NDLTD
topic 530.1
Reaction-diffusion equations
spellingShingle 530.1
Reaction-diffusion equations
Howard, Martin
Non-equilibrium dynamics of reaction-diffusion systems
description Fluctuations are known to radically alter the behaviour of reaction-diffusion systems. Below a certain upper critical dimension d<sub>c</sub> , this effect results in the breakdown of traditional approaches, such as mean field rate equations. In this thesis we tackle this fluctuation problem by employing systematic field theoretic/renormalisation group methods, which enable perturbative calculations to be made below d<sub>c</sub>. We first consider a steady state reaction front formed in the two species irreversible reaction A + B → Ø. In one dimension we demonstrate that there are two components to the front - one an intrinsic width, and one caused by the ability of the centre of the front to wander. We make theoretical predictions for the shapes of these components, which are found to be in good agreement with our one dimensional simulations. In higher dimensions, where the intrinsic component dominates, we also make calculations for its asymptotic profile. Furthermore, fluctuation effects lead to a prediction of asymptotic power law tails in the intrinsic front in all dimensions. This effect causes high enough order spatial moments of a time dependent reaction front to exhibit multiscaling. The second system we consider is a time dependent multispecies reaction-diffusion system with three competing reactions A+A → Ø, B + B → Ø, and A + B → Ø, starting with homogeneous initial conditions. Using our field theoretic formalism we calculate the asymptotic density decay rates for the two species for d ≤ d<sub>c</sub>. These calculations are compared with other approximate methods, such as the Smoluchowski approach, and also with previous simulations and exact results.
author Howard, Martin
author_facet Howard, Martin
author_sort Howard, Martin
title Non-equilibrium dynamics of reaction-diffusion systems
title_short Non-equilibrium dynamics of reaction-diffusion systems
title_full Non-equilibrium dynamics of reaction-diffusion systems
title_fullStr Non-equilibrium dynamics of reaction-diffusion systems
title_full_unstemmed Non-equilibrium dynamics of reaction-diffusion systems
title_sort non-equilibrium dynamics of reaction-diffusion systems
publisher University of Oxford
publishDate 1996
url http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.318754
work_keys_str_mv AT howardmartin nonequilibriumdynamicsofreactiondiffusionsystems
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