Effect of adsorption coefficient and sorption intensity on the spatiotemporal variation of contaminant concentration in saturated porous media using the fractional advection–dispersion equation

This study presents a numerical solution of time and space fractional advection–dispersion equation (FADE) using the explicit Euler method, combined with the standard Grünwald formula and the Caputo fractional time derivative. The research aims to contribute to a better understanding and optimizatio...

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Bibliographic Details
Published inDiscover applied sciences Vol. 7; no. 9; p. 993
Main Authors Yonti Madie, Calvia, Nonki, Rodric Merime, Yossa Dansi, Denis William, Nkili, Francky Joël, Togue Kamga, Fulbert
Format Journal Article
LanguageEnglish
Published Cham Springer International Publishing 26.08.2025
Springer Nature B.V
Subjects
Adsorption
Advection
Applied and Technical Physics
Aquifers
Boundary conditions
Chemistry/Food Science
Contaminants
Earth Sciences
Engineering
Environment
Environmental impact
Fractals
Groundwater
Materials Science
Mathematical models
Numerical analysis
Optimization
Parameters
Partial differential equations
Pollutants
Pollution dispersion
Porous media
Retention
Fractional advection–dispersion
Groundwater
Contaminant
Freundlich parameter
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Summary:This study presents a numerical solution of time and space fractional advection–dispersion equation (FADE) using the explicit Euler method, combined with the standard Grünwald formula and the Caputo fractional time derivative. The research aims to contribute to a better understanding and optimization of pollutant retention in subsurface environments, accounting for Freundlich parameters. The FADE model demonstrated a greater capacity for solute mass retention. Additionally, in a saturated porous medium, solute movement is more effectively influenced by the absorption parameter associated with the retardation factor. In other words, this parameter has a notable impact on pollutant dispersion in porous media. This work emphasizes the importance of accurately characterizing these parameters to optimize pollutant retention and better understand transport mechanisms in complex porous media. Article Highlights FADE improves the modeling of solute mass retention in saturated porous media. Freundlich parameters strongly influence solute dispersion and movement in saturated environments. Accurate characterization of Freundlich and retardation parameters optimizes pollutant retention and transport.
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ISSN:3004-9261
2523-3963
3004-9261
2523-3971
DOI:10.1007/s42452-025-06903-8