Numerical solutions for solute transport in unconfined aquifers

Guvanasen, V.; Volker, R. E.

doi:10.1002/fld.1650030203

Cited by 52 publications

(21 citation statements)

References 11 publications

(4 reference statements)

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“…The partial differential advection-diffusion equation (ADE) describes water transfer in soils (Parlange, 1980), dispersion of tracers in porous media (Fattah and Hoopes, 1985), the spread of pollutants in rivers and streams (Chatwin and Allen, 1985), the dispersion of dissolved material in estuaries and coastal seas (Holly and Usseglio-Polatera, 1984), contaminant dispersion in shallow lakes (Salmon et al, 1980), the absorption of chemicals into beds (Lapidus and Amundston, 1952), long-range transport of pollutants in the atmosphere (Zlatev et al, 1984), forced cooling by fluids of solid material such as windings in turbo generators (Gane and Stephenson, 1979), thermal pollution in river systems (Chaudhry et al, 1983), flow in porous media (Kumar, 1988) and dispersion of dissolved salts in groundwater (Guvanasen and Volker, 1983). Logan and Zlotnik (1995) proposed analytical solutions with a decay term for periodic input conditions through a semiinfinite domain to address fluctuations of the groundwater table and flow patterns caused by the periodicity of the sea level.…”

Section: Introductionmentioning

confidence: 99%

Explicit finite-difference solution of two-dimensional solute transport with periodic flow in homogenous porous media

Djordjevich

Savović

Janićijević

2017

Journal of Hydrology and Hydromechanics

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Abstract:The two-dimensional advection-diffusion equation with variable coefficients is solved by the explicit finitedifference method for the transport of solutes through a homogenous two-dimensional domain that is finite and porous. Retardation by adsorption, periodic seepage velocity, and a dispersion coefficient proportional to this velocity are permitted. The transport is from a pulse-type point source (that ceases after a period of activity). Included are the firstorder decay and zero-order production parameters proportional to the seepage velocity, and periodic boundary conditions at the origin and at the end of the domain. Results agree well with analytical solutions that were reported in the literature for special cases. It is shown that the solute concentration profile is influenced strongly by periodic velocity fluctuations. Solutions for a variety of combinations of unsteadiness of the coefficients in the advection-diffusion equation are obtainable as particular cases of the one demonstrated here. This further attests to the effectiveness of the explicit finite difference method for solving two-dimensional advection-diffusion equation with variable coefficients in finite media, which is especially important when arbitrary initial and boundary conditions are required.

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Section: Introductionmentioning

confidence: 99%

Explicit finite-difference solution of two-dimensional solute transport with periodic flow in homogenous porous media

Djordjevich

Savović

Janićijević

2017

Journal of Hydrology and Hydromechanics

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“…''-I2 All of these methods involve a spread of at least three grid points in space except those of Holly and Preissmann, l 3 Lam and Simpson, l4 and von Rosenberg, l5 which use only two spatial grid points. However, the first two of these methods require the solution of an additional equation at each grid point for the computation of the spatial gradient of i , have a derivative boundary condition at x = 0 replacing condition (4) and require initial values of the spatial gradient to be given in addition to (2). The third method has only restricted application because it requires the Courant number to have the fixed value of 1.…”

Section: O < T < Tmentioning

confidence: 99%

A compact unconditionally stable finite‐difference method for transient one‐dimensional advection‐diffusion

Noye

1991

Commun. appl. numer. methods

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SUMMARYA new compact second-order finite-difference method for solving the time-dependent one-dimensional constant-coefficient advection-diffusion equation is developed. It involves a spread of only two grid points in space and two levels in time. It may be evaluated in an explicit marching manner and requires the availability of only upstream boundary values. It is unconditionally stable and has the property of giving 'non-negative' values for a large range of Courant and diffusion numbers. For all grid Reynolds numbers greater than 2 it is shown to be more accurate than commonly used second-order methods, all of which involve a spread of three grid points in space.

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“…It has been used to describe heat transfer in a draining film [1], mass transfer [2], flow in porous media [3] and charge transport in semi-conductor devices [4]. The 3D advection-diffusion equation is given by: ∂u ∂t + β x ∂u ∂x + β y ∂u ∂y + β z ∂u ∂z = α x ∂ 2 u ∂x 2 + α y…”

Section: Introductionmentioning

confidence: 99%

Comparative study of some numerical methods to solve a 3D advection-diffusion equation

Appadu¹,

Djoko²,

Gidey³

2017

AIP Conference Proceedings

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Abstract. In this work, three finite difference methods have been used to solve a three dimensional advection-diffusion equation with given initial and boundary conditions. The three methods are fourth order finite difference method, Crank-Nicolson and Implicit Chapeau Function. We compare the performance of the methods by computing L 2 error, L ∞ error and some performance indices such as mass distribution ratio (MDR), mass conservation ratio (MCR), total mass and R 2 which is a measure of total variation in particle distribution.

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Numerical solutions for solute transport in unconfined aquifers

Cited by 52 publications

References 11 publications

Explicit finite-difference solution of two-dimensional solute transport with periodic flow in homogenous porous media

Explicit finite-difference solution of two-dimensional solute transport with periodic flow in homogenous porous media

A compact unconditionally stable finite‐difference method for transient one‐dimensional advection‐diffusion

Comparative study of some numerical methods to solve a 3D advection-diffusion equation

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