Explicit formulas for reaction probability in reaction-diffusion experiments

M. Wallace; R. Feres; G. Yablonsky; A. Stern

doi:10.1016/j.compchemeng.2016.06.007

Explicit formulas for reaction probability in reaction-diffusion experiments

M. Wallace, R. Feres, G. Yablonsky, A. Stern

Department of Mathematics

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

A computational procedure is developed for determining the conversion probability for reaction-diffusion systems in which a first-order catalytic reaction is performed over active particles. We apply this general method to systems on metric graphs, which may be viewed as 1-dimensional approximations of 3-dimensional systems, and obtain explicit formulas for conversion. We then study numerically a class of 3-dimensional systems and test how accurately they are described by model formulas obtained for metric graphs. The optimal arrangement of active particles in a 1-dimensional multiparticle system is found, which is shown to depend on the level of catalytic activity: conversion is maximized for low catalytic activity when all particles are bunched together close to the point of gas injection, and for high catalytic activity when the particles are evenly spaced.

Original language	English
Pages (from-to)	612-622
Number of pages	11
Journal	Computers and Chemical Engineering
Volume	125
DOIs	https://doi.org/10.1016/j.compchemeng.2016.06.007
State	Published - Jun 9 2019

Keywords

Computer simulation
Fractional conversion
Heterogeneous catalysis
Temporal analysis of products

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10.1016/j.compchemeng.2016.06.007

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title = "Explicit formulas for reaction probability in reaction-diffusion experiments",

abstract = "A computational procedure is developed for determining the conversion probability for reaction-diffusion systems in which a first-order catalytic reaction is performed over active particles. We apply this general method to systems on metric graphs, which may be viewed as 1-dimensional approximations of 3-dimensional systems, and obtain explicit formulas for conversion. We then study numerically a class of 3-dimensional systems and test how accurately they are described by model formulas obtained for metric graphs. The optimal arrangement of active particles in a 1-dimensional multiparticle system is found, which is shown to depend on the level of catalytic activity: conversion is maximized for low catalytic activity when all particles are bunched together close to the point of gas injection, and for high catalytic activity when the particles are evenly spaced.",

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AU - Wallace, M.

AU - Feres, R.

AU - Yablonsky, G.

AU - Stern, A.

PY - 2019/6/9

Y1 - 2019/6/9

N2 - A computational procedure is developed for determining the conversion probability for reaction-diffusion systems in which a first-order catalytic reaction is performed over active particles. We apply this general method to systems on metric graphs, which may be viewed as 1-dimensional approximations of 3-dimensional systems, and obtain explicit formulas for conversion. We then study numerically a class of 3-dimensional systems and test how accurately they are described by model formulas obtained for metric graphs. The optimal arrangement of active particles in a 1-dimensional multiparticle system is found, which is shown to depend on the level of catalytic activity: conversion is maximized for low catalytic activity when all particles are bunched together close to the point of gas injection, and for high catalytic activity when the particles are evenly spaced.

AB - A computational procedure is developed for determining the conversion probability for reaction-diffusion systems in which a first-order catalytic reaction is performed over active particles. We apply this general method to systems on metric graphs, which may be viewed as 1-dimensional approximations of 3-dimensional systems, and obtain explicit formulas for conversion. We then study numerically a class of 3-dimensional systems and test how accurately they are described by model formulas obtained for metric graphs. The optimal arrangement of active particles in a 1-dimensional multiparticle system is found, which is shown to depend on the level of catalytic activity: conversion is maximized for low catalytic activity when all particles are bunched together close to the point of gas injection, and for high catalytic activity when the particles are evenly spaced.

KW - Computer simulation

KW - Fractional conversion

KW - Heterogeneous catalysis

KW - Temporal analysis of products

UR - https://www.scopus.com/pages/publications/84999016919

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DO - 10.1016/j.compchemeng.2016.06.007

M3 - Article

AN - SCOPUS:84999016919

SN - 0098-1354

VL - 125

SP - 612

EP - 622

JO - Computers and Chemical Engineering

JF - Computers and Chemical Engineering

ER -

Explicit formulas for reaction probability in reaction-diffusion experiments

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Keywords

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