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Geotechnical and Geological Engineering
Erschienen in: Geotechnical and Geological Engineering 1/2013

01.02.2013 | Original paper

Comparison Between Analytical and Numerical Methods in Evaluating the Pollution Transport in Porous Media

verfasst von: A. R. Estabragh, M. R. S. Pereshkafti, A. A. Javadi

Erschienen in: Geotechnical and Geological Engineering | Ausgabe 1/2013

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Abstract

Contaminant transport modelling in environmental engineering is generally conducted to evaluate the potential impact of contaminant migration on the subsurface environment or for interpreting tracer tests or groundwater quality data. In the past few decades a number of mathematical models have been established for evaluating the migration of pollution as indicated in the literature. This paper presents a comparison between a number of analytical and numerical models in evaluating pollution transport in soils. Three analytical models and a finite element model developed in this research are used for comparing four numerical examples under different conditions. Four cases of advection dominated problem with line source boundary, advection dominated problem with semi-line source boundary, advection–dispersion–sorption problem with line source boundary and advection–dispersion–sorption problem with semi-line source are considered. Based on the results the best analytical model that has a higher accuracy is recommended for practical applications.
Vorheriger Artikel Influence of Water Content on Mechanical Properties of Improved Clayey Soil Using Steel Slag
Nächster Artikel Multiphase Extraction of Light Non-aqueous Phase Liquid (LNAPL) Using Prefabricated Vertical Wells

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Literatur
Aziz CE, Newell CJ, Gonzales JR, Haas P, Clement TP, SunY (2000) BIOCHLOR: natural attenuation decision support system v. 1.0, User’s manual. U.S. EPA Report EPA/600/R-00/008. U.S. Environmental Protection Agency, Cincinnati, Ohio
Batu V (1996) A generalized three-dimensional analytical solute transport model for multiple rectangular first-type sources. J Hydrol 174:57–82CrossRef
Bear J (1979) Hydraulics of ground water. McGraw-Hill, New York City
Brooks AN, Hughes TJR (1982) Streamline upwind/Petrov–Galerkin formulations for convective dominated flows with particular emphasis on the incompressible Navier–Stokes equations. Comput Methods Appl Mech Eng 32:199–259CrossRef
Cleary R, Ungs MJ (1978) Analytical models for groundwater pollution and hydrology. Report No. 78-WR-15. Water Resources Program, Princeton University, Princeton, New Jersey
Clement TP, Truex MJ, Lee P (2002) A case study for demonstrating the application of U.S. EPA’s monitored natural attenuation screening protocol at a hazardous waste site. J Contam Hydrol 59(1–2):133–162CrossRef
Domenico PA (1987) An analytical model for multidimensional transport of a decaying contaminant species. J Hydrol 91(1–2):49–58CrossRef
Domenico PA, Paliciauskas VV (1982) Alternative boundaries in solid waste management. Ground Water 20(3):303–311CrossRef
Domenico PA, Robbins GA (1985) A new method of contaminant plume analysis. Ground Water 23(4):476–485CrossRef
Donea J, Huerta A (2003) A finite element methods for flow problem. John Willey, New YorkCrossRef
El-Zein A (2005) Exponential finite elements for diffusion-advection problems. Int J Numer Meth Eng 62:2086–2103CrossRef
El-Zein A, Booker JR (1999) Ground water pollution by organic compounds: a two- dimensional solution of contaminant transport equations in stratified porous media with multiple sources of non-equilibrium partitioning. Int J Numer Anal Geomech 23:1717–1732CrossRef
El-Zein A, Carter JR (2003) A multiple-porosity finite-element model of reactive contaminants in soils. Second MIT conference on computational fluid and solid mechanics. Massachusetts Institute of Technology, Cambridge
Fletcher CAJ (1988) Computational techniques for fluid dynamics, fundamental and general techniques. Springer, BerlinCrossRef
Franca LP, Frey SL, Hughes TJR (1992) Stabilized finite element methods: application to the adjective-diffusive model. Comput Methods Appl Mech Eng 95:253–276CrossRef
Guerghian AB, Ward DS, Cleary RWA (1980) finite element model for the migration of leachate from a sanitary landfill in Long Island. New York. Water Resour Bull 16(5):900–906CrossRef
Guyonnet D, Neville C (2004) Dimensionless analysis of two analytical solutions for 3-D solute transport in groundwater. J Contam Hydrol 75(1–2):141–153CrossRef
Hoyakorn PS (1977) Solution of steady-state convective transport equation using and upwind finite element scheme. Appl Math Model 1:187–195CrossRef
Hoyakorn PS, Nikuha K (1979) Solution of transient transport equation using an upstream finite element scheme. Appl Math Model 3:7–17CrossRef
Huyakorn PS, Ungs MJ, Mulkey LA, Sudicky EA (1987) A three-dimensional analytical method for predicting leach ate migration. Ground Water 25(5):588–598CrossRef
Leij FJ, Skaggs TH, Van Genuchten MT (1991) Analytical solutions for solute transport in three-dimensional semi-infinite porous media. Water Resour Res 27:2719–2733CrossRef
Martyn-Hayden J, Robbins GA (1997) Plume distortion and apparent attenuation due to concentration averaging in monitoring wells. Ground Water 35(2):339–346CrossRef
Praveen Kumar R, Dadagoudar GR (2009) Modeling of contaminant transport through landfill liners using EFGM. Int J Numer Anal Methods Geomech 34(7):661–688
Sagar B (1982) Dispersion in three dimensions: approximate analytical solutions. ASCE J Hydraul Div 108(HY1):47–62
Srinivasan V, Clement TP, Lee KK (2007) Domenico solution-is it valid. Ground Water 45(2):136–146CrossRef
Sudicky EA (1989) The Laplace transforms Galerkin technique: a time-continuous finite element theory and application to mass transport in groundwater. Water Resour Res 25:1833–1846CrossRef
West MR, Kueper BH (2004) Natural attenuation of solute plumes in bedded fractured rock. In: Proceedings of USEPA/NGWA fractured rock conference. National Ground Water Association, Portland, Maine, pp 388–401
West MR, Kueper BH, Ungs MJ (2007) On the use and error of approximation in the Domenico (1987) solution. Ground Water 45(2):126–135
Wexler EJ (1992) Analytical solutions for one-, two-, and three-dimensional solute transport in ground-water systems with uniform flow. USGS—TWRI Book 3, Chapter B7. USGS, Reston, Virginia
Zairi M, Rouis MJ (2000) Numerical and experimental simulation of pollutants migration in porous media. Bull Eng Geol Environ 59:231–238CrossRef
Zienkiewicz OC, Taylor RL (1991) The finite element method: solid and fluid mechanics dynamics and non-linearity, vol 2, 4th edn. McGraw-Hill Book Company, London
Metadaten
Titel
Comparison Between Analytical and Numerical Methods in Evaluating the Pollution Transport in Porous Media
verfasst von
A. R. Estabragh
M. R. S. Pereshkafti
A. A. Javadi
Publikationsdatum
01.02.2013
Verlag
Springer Netherlands
Erschienen in
Geotechnical and Geological Engineering / Ausgabe 1/2013
Print ISSN: 0960-3182
Elektronische ISSN: 1573-1529
DOI
https://doi.org/10.1007/s10706-012-9566-6

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