Mixing, entropy and reactive solute transport

Gabriele Chiogna; David L. Hochstetler; Alberto Bellin; Peter K. Kitanidis; Massimo Rolle

doi:10.1029/2012GL053295

Mixing, entropy and reactive solute transport

Gabriele Chiogna, David L. Hochstetler, Alberto Bellin, Peter K. Kitanidis, Massimo Rolle

Research output: Contribution to journal › Journal article › Research › peer-review

Abstract

Mixing processes significantly affect reactive solute transport in fluids. For example, contaminant degradation in environmental aquatic systems can be limited either by the availability of one or more reactants, brought into contact by physical mixing, or by the kinetics of the (bio)chemical transformations. Appropriate metrics are needed to accurately quantify the interplay between mixing and reactive processes. The exponential of the Shannon entropy of the concentration probability distribution has been proposed and applied to quantify the dilution of conservative solutes either in a given volume (dilution index) or in a given water flux (flux-related dilution index). In this work we derive the transport equation for the entropy of a reactive solute. Adopting a flux-related framework, we show that the degree of uniformity of the solute mass flux distribution for a reactive species and its rate of change are informative measures of physical and (bio)chemical processes and their complex interaction. Citation: Chiogna, G., D. L. Hochstetler, A. Bellin, P. K. Kitanidis, and M. Rolle (2012), Mixing, entropy and reactive solute transport, Geophys. Res. Lett., 39, L20405, doi:10.1029/2012GL053295.

Original language	English
Journal	Geophysical Research Letters
Volume	39
Issue number	20
ISSN	0094-8276
DOIs	https://doi.org/10.1029/2012GL053295
Publication status	Published - 2012
Externally published	Yes

Keywords

GEOSCIENCES,
DISPERSION
DILUTION
MEDIA
Probability distributions
Solute transport
Mixing
Appropriate metrics
Aquatic system
Chemical process
Chemical transformations
Complex interaction
Contaminant degradation
Flux distributions
Informative measures
Mixing process
Physical mixing
Rate of change
Reactive process
Reactive solutes
Reactive species
Shannon entropy
Transport equation
Water flux

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title = "Mixing, entropy and reactive solute transport",

abstract = "Mixing processes significantly affect reactive solute transport in fluids. For example, contaminant degradation in environmental aquatic systems can be limited either by the availability of one or more reactants, brought into contact by physical mixing, or by the kinetics of the (bio)chemical transformations. Appropriate metrics are needed to accurately quantify the interplay between mixing and reactive processes. The exponential of the Shannon entropy of the concentration probability distribution has been proposed and applied to quantify the dilution of conservative solutes either in a given volume (dilution index) or in a given water flux (flux-related dilution index). In this work we derive the transport equation for the entropy of a reactive solute. Adopting a flux-related framework, we show that the degree of uniformity of the solute mass flux distribution for a reactive species and its rate of change are informative measures of physical and (bio)chemical processes and their complex interaction. Citation: Chiogna, G., D. L. Hochstetler, A. Bellin, P. K. Kitanidis, and M. Rolle (2012), Mixing, entropy and reactive solute transport, Geophys. Res. Lett., 39, L20405, doi:10.1029/2012GL053295.",

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year = "2012",

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AU - Chiogna, Gabriele

AU - Hochstetler, David L.

AU - Bellin, Alberto

AU - Kitanidis, Peter K.

AU - Rolle, Massimo

PY - 2012

Y1 - 2012

N2 - Mixing processes significantly affect reactive solute transport in fluids. For example, contaminant degradation in environmental aquatic systems can be limited either by the availability of one or more reactants, brought into contact by physical mixing, or by the kinetics of the (bio)chemical transformations. Appropriate metrics are needed to accurately quantify the interplay between mixing and reactive processes. The exponential of the Shannon entropy of the concentration probability distribution has been proposed and applied to quantify the dilution of conservative solutes either in a given volume (dilution index) or in a given water flux (flux-related dilution index). In this work we derive the transport equation for the entropy of a reactive solute. Adopting a flux-related framework, we show that the degree of uniformity of the solute mass flux distribution for a reactive species and its rate of change are informative measures of physical and (bio)chemical processes and their complex interaction. Citation: Chiogna, G., D. L. Hochstetler, A. Bellin, P. K. Kitanidis, and M. Rolle (2012), Mixing, entropy and reactive solute transport, Geophys. Res. Lett., 39, L20405, doi:10.1029/2012GL053295.

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KW - Chemical transformations

KW - Complex interaction

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JO - Geophysical Research Letters

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ER -

Mixing, entropy and reactive solute transport

Abstract

Keywords

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