Register      Login
Soil Research Soil Research Society
Soil, land care and environmental research
Shopping Cart: ( empty )
You are here: Home > Journals > SR > SR04111
RESEARCH ARTICLE
Contents Vol 43(6)

Modelling velocity and retardation factor of a nonlinearly sorbing solute plume

M. A. Mojid A C and H. Vereecken B
+ Author Affiliations
- Author Affiliations

A Department of Irrigation and Water Management, Bangladesh Agricultural University, Mymensingh − 2202, Bangladesh.

B Institute of Chemistry and Dynamics of the Geosphere, ICG – IV: Agrosphere, Forschungszentrum Juelich GmbH, D-52425 Juelich, Germany.

C Corresponding author. Email: ma_mojid@yahoo.com

Australian Journal of Soil Research 43(6) 735-743 https://doi.org/10.1071/SR04111
Submitted: 15 July 2004  Accepted: 12 May 2005   Published: 22 September 2005

Abstract

This study, considering evidences of slower sorption rates of reactive solutes in the field than in laboratory, quantifies the velocity and retardation factor of a sodium fluorescein (uranin: C20H10Na2O5) plume over its travel path in a heterogeneous aquifer. The transport process of uranin was evaluated by batch experiments and from breakthrough curves (BTCs) by using solute-transport models. Method of time moments analysed BTCs of uranin and bromide to derive the velocity and retardation factor.

A constant velocity of the bromide plume, 0.64 m/day, implies a spatially and temporally uniform velocity field where groundwater flows at steady-state condition. A large dimensionless index (195) of chemical non-equilibrium model and equilibrium distribution coefficient (0.32) of uranin are indicative of chemical non-equilibrium transport process.

The travel time of uranin plume increases asymptotically, following power law, with travel path of the plume. Good agreement of the exponent of power law with that of Freundlich isotherm is a result of nonlinear sorption, and provides an independent way of estimating the exponent of the isotherm. The local velocity of the plume decreases asymptotically in time and is predicted by the derivative of the relationship between travel path and travel time of the plume. The retardation factor, which increases in time following power law, when estimated from the local velocity, is considerably larger than that estimated from travel time of the plume.

Additional keywords: reactive solute, kinetically controlled sorption, travel time, power law relation.


Acknowledgments

During this work, the principal author held a postdoctoral research fellowship offered by the Alexander von Humboldt Foundation, Germany, and was on deputation from the Bangladesh Agricultural University (BAU), Mymensingh. The authors gratefully acknowledge the assistances of both the Alexander von Humboldt Foundation and BAU authority to carry out this research.


References


Ball WP (1989) Equilibrium partitioning and diffusion rate studies with halogenated organic chemicals and sandy aquifer material, PhD thesis, Stanford University, Stanford, USA.

Bosma WJP, van der Zee SEATM (1993) Transport of reacting solute in a one-dimensional chemically heterogeneous porous medium. Water Resources Research 29, 117–131.
Crossref | GoogleScholarGoogle Scholar | open url image1

Brusseau ML (1998) Non-ideal transport of reactive solutes in heterogeneous porous media: 3. Model testing and data analysis using calibration versus prediction. Journal of Hydrology 209, 147–165.
Crossref | GoogleScholarGoogle Scholar | open url image1

Burr DT, Sudicky EA, Naff LR (1994) Non-reactive and reactive solute transport in three-dimensional heterogeneous porous media: Mean displacement, plume spreading, and uncertainty. Water Resources Research 30, 791–815.
Crossref | GoogleScholarGoogle Scholar | open url image1

Chrysikopoulos CV, Kitanidis PK, Roberts PV (1992) Macrodispersion of sorbing solutes in heterogeneous porous formations with spatially periodic retardation factor and velocity field. Water Resources Research 28, 1517–1530.
Crossref | GoogleScholarGoogle Scholar | open url image1

Coats KH, Smith BD (1964) Dead end pore volume and dispersion in porous media. Journal of Society of Petroleum Engineering 4, 73–84. open url image1

Cushey MA, Rubin Y (1997) Field-scale transport of non-polar organic solutes in 3-D heterogeneous aquifers. Environmental Science and Technology 31, 1259–1268.
Crossref | GoogleScholarGoogle Scholar | open url image1

Dagan, G (1989). ‘Flow and transport in porous formations.’ (Springer-Verlag: New York)

Dagan G, Cvetkovic V (1993) Spatial moments of a kinetically sorbing solute plume in a heterogeneous aquifer. Water Resources Research 29, 4053–4063.
Crossref | GoogleScholarGoogle Scholar | open url image1

DeSmedt F, Wierenga PJ (1979) A generalized solution for solute flow in soils with mobile and immobile water. Water Resources Research 15, 1137–1141. open url image1

Döring U (1997) Transport der reactiven stoffe eosin, uranin, und lithium in einem heterogenen grundwasserleiter, PhD thesis, Christian-Albrechts Universität, Kiel, Germany.

Eiswirth M, Hötzl H (1994) Groundwater contamination by leaky sewerage systems. ‘Water down under. Proceedings of the 25th International Congress, International Association of Hydrogeologists’. Adelaide, Australia. ( : )


Garabedian SP (1987) Large-scale dispersive transport in aquifers: Field experiments and reactive transport theory. PhD thesis, Cambridge University, Cambridge, UK.

van Genuchten MTh (1985) A general approach for modeling solute transport in structured soils. In ‘Hydrogeology of rocks of low permeability. Proceedings of the 17th International Congress, International Association of Hydrogeologists’. Tucson, AR.


Jaekel U, Georgescu A, Vereecken H (1996) Asymptotic analysis of nonlinear equilibrium solute transport in porous media. Water Resources Research 32, 3093–3098.
Crossref | GoogleScholarGoogle Scholar | open url image1

Kabala ZJ, Sposito G (1991) A stochastic model of reactive solute transport with time-varying velocity in a heterogeneous aquifer. Water Resources Research 27, 341–350.
Crossref | GoogleScholarGoogle Scholar | open url image1

Mackay DM, Freyberg DL, Roberts PV, Cherry JA (1986) A natural gradient experiment on solute transport in a sand aquifer, 1, Approach and overview of plume movement. Water Resources Research 22, 2017–2029. open url image1

Mikulla CH, Einsiedl F, Schumprecht CH, Wohnlich S (1997) Sorption of uranin and eosin on an aquifer material containing high Corg. ‘Tracer hydrology. Proceedings of the 7th SWT’. Portoroz, Balkema.


Miralles-Wilhelm F, Gelhar LW (1996) Stochastic analysis of sorption macro-kinetics in heterogeneous aquifers. Water Resources Research 32, 1541–1549.
Crossref | GoogleScholarGoogle Scholar | open url image1

Neretnieks I (2002) A stochastic multi-channel model for solute-transport analysis of tracer tests in fractured rock. Journal of Contaminant Hydrology 55, 175–211.
Crossref | GoogleScholarGoogle Scholar | PubMed | open url image1

Nkedi-Kizza P, Biggar JW, van Genuchten MTh, Wierenga PJ, Selim MH, Davidson JM, Nielsen DR (1983) Modeling tritium and chloride 36 transport through an aggregated oxisol. Water Resources Research 19, 691–700. open url image1

Ptacek CJ, Gillham RW (1992) Laboratory and field measurements of non-equilibrium transport in the Borden aquifer, Ontario, Canada. Journal of Contaminant Hydrology 10, 119–158.
Crossref | GoogleScholarGoogle Scholar | open url image1

Quinodoz HAM, Valocchi AJ (1993) Stochastic analysis of the transport of kinetically sorbing solutes in aquifers with randomly heterogeneous hydraulic conductivity. Water Resources Research 29, 3227–3240.
Crossref | GoogleScholarGoogle Scholar | open url image1

Roberts PV, Goltz MN, Mackay DM (1986) A natural gradient experiment on solute transport in a sand aquifer. 3. Retardation estimates and mass balances for organic solutes. Water Resources Research 22, 2047–2058. open url image1

Sudicky EA (1986) A natural gradient experiment on solute transport in a sand aquifer: spatial variability of hydraulic conductivity and its role in the dispersion process. Water Resources Research 22, 2069–2082. open url image1

Valocchi AJ (1985) Validity of the local equilibrium assumption for modeling sorbing solute transport through homogeneous soils. Water Resources Research 21, 808–820. open url image1

Van der Zee SEATM, van Riemsdijk WH (1987) Transport of reactive solute in spatially variable soil systems. Water Resources Research 23, 2059–2069. open url image1

Vanderborght I, Vereecken H (2001) Analyses of locally measured bromide breakthrough curves from a natural gradient tracer experiment at Krauthausen. Journal of Contaminant Hydrology 48, 23–43.
Crossref | GoogleScholarGoogle Scholar | PubMed | open url image1

Vereecken H, Döring U, Hardelauf H, Jaekel U, Hashagen U, Neuendorf O, Schwarze H, Seidemann R (2000) Analysis of solute transport in a heterogeneous aquifer: the Krauthausen field experiments. Journal of Contaminant Hydrology 45, 329–358.
Crossref | GoogleScholarGoogle Scholar | open url image1

Vereecken H, Jaekel U, Esser O, Nitzsche O (1999) Solute transport of bromide, uranin and LiCl using breakthrough curves from aquifer sediment. Journal of Contaminant Hydrology 39, 7–34.
Crossref | GoogleScholarGoogle Scholar | open url image1

Vereecken H, Jaekel U, Schwarze H (2002) Analysis of the long-term behavior of solute transport with non-linear equilibrium sorption using breakthrough curves and temporal moments. Journal of Contaminant Hydrology 56, 271–294.
Crossref | GoogleScholarGoogle Scholar | PubMed | open url image1

Wood WW, Kraemer TF, Hearn PP (1990) Intragranular diffusion: An important mechanism influencing solute transport in classic aquifers. Science 247, 1569–1572. open url image1