Relative dispersion for solute flux in aquifers

ROKO ANDRIČEVIĆ; VLADIMIR CVETKOVIĆ

doi:10.1017/S0022112098008751

Abstract

The relative dispersion framework for the non-reactive and reactive solute flux in aquifers is presented in terms of the first two statistical moments. The solute flux is described as a space–time process where time refers to the solute flux breakthrough and space refers to the transverse displacement distribution at the control plane. The statistics of the solute flux breakthrough and transversal displacement distributions are derived by analysing the motion of particle pairs. The results indicate that the relative dispersion formulation approaches the absolute dispersion results on increasing the source size (e.g. >10 heterogeneity scales). The solute flux statistics, when sampling volume is accounted for, show a flattened distribution for the solute flux variance in the space–time domain. For reactive solutes, the solute flux shows a tailing phenomenon in time while solute flux variance exhibits bi-modality in transverse distribution during the recession stage of the solute breakthrough. The solute flux correlation structure is defined as an integral measure over space and time, providing a potentially useful tool for sampling design in the subsurface.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Andričević, Roko 1998. Effects of local dispersion and sampling volume on the evolution of concentration fluctuations in aquifers. Water Resources Research, Vol. 34, Issue. 5, p. 1115.

Pohll, Greg Hassan, Ahmed E. Chapman, Jenny B. Papelis, Charalambos and Andricevic, Roko 1999. Modeling Ground Water Flow and Radioactive Transport in a Fractured Aquifer. Groundwater, Vol. 37, Issue. 5, p. 770.

Kaluarachchi, Jagath J. Cvetkovic, Vladimir and Berglund, Sten 2000. Stochastic analysis of oxygen- and nitrate-based biodegradation of hydrocarbons in aquifers. Journal of Contaminant Hydrology, Vol. 41, Issue. 3-4, p. 335.

Zhang, Dongxiao Andricevic, Roko Sun, Alexander Y. Hu, Xiaolong and He, Guowei 2000. Solute flux approach to transport through spatially nonstationary flow in porous media. Water Resources Research, Vol. 36, Issue. 8, p. 2107.

Cvetkovic, V. 2000. Colloid-facilitated tracer transport by steady random ground-water flow. Physics of Fluids, Vol. 12, Issue. 9, p. 2279.

Hassan, A.E. 2001. Water flow and solute mass flux in heterogeneous porous formations with spatially random porosity. Journal of Hydrology, Vol. 242, Issue. 1-2, p. 1.

Hassan, Ahmed E. Andricevic, Roko and Cvetkovic, Vladimir 2001. Computational issues in the determination of solute discharge moments and implications for comparison to analytical solutions. Advances in Water Resources, Vol. 24, Issue. 6, p. 607.

Fiori, Aldo 2001. Dispersion in Heterogeneous Geological Formations. p. 69.

Painter, S. Cvetkovic, V. and Turner, D.R. 2001. Effect of Heterogeneity on Radionuclide Retardation in the Alluvial Aquifer Near Yucca Mountain, Nevada. Groundwater, Vol. 39, Issue. 3, p. 326.

Hassan, Ahmed E. Andricevic, Roko and Cvetkovic, Vladimir 2002. Evaluation of analytical solute discharge moments using numerical modeling in absolute and relative dispersion frameworks. Water Resources Research, Vol. 38, Issue. 2,

Hu, Bill X. Wu, Jichun Panorska, Ania K. Zhang, Dongxiao and He, Changming 2003. Stochastic study on groundwater flow and solute transport in a porous medium with multi-scale heterogeneity. Advances in Water Resources, Vol. 26, Issue. 5, p. 541.

Wu, Jichun Hu, Bill X. Zhang, Dongxiao and Shirley, Craig 2003. A three-dimensional numerical method of moments for groundwater flow and solute transport in a nonstationary conductivity field. Advances in Water Resources, Vol. 26, Issue. 11, p. 1149.

Cirpka, Olaf A. and Attinger, Sabine 2003. Effective dispersion in heterogeneous media under random transient flow conditions. Water Resources Research, Vol. 39, Issue. 9,

Wu, Jichun Hu, Bill X. and Zhang, Dongxiao 2003. Applications of nonstationary stochastic theory to solute transport in multi-scale geological media. Journal of Hydrology, Vol. 275, Issue. 3-4, p. 208.

Neupauer, R.M and Wilson, J.L 2004. Forward and backward location probabilities for sorbing solutes in groundwater. Advances in Water Resources, Vol. 27, Issue. 7, p. 689.

Jose, Surabhin C. Rahman, M. Arifur and Cirpka, Olaf A. 2004. Large‐scale sandbox experiment on longitudinal effective dispersion in heterogeneous porous media. Water Resources Research, Vol. 40, Issue. 12,

Lessoff, S. C. and Indelman, P. 2004. Stochastic determination of three‐dimensional capture zones for a fully penetrating well. Water Resources Research, Vol. 40, Issue. 3,

Sun, Alexander Y. and Zhang, Dongxiao 2004. A Solute Flux Approach to Transport through Bounded, Unsaturated Heterogeneous Porous Media. Vadose Zone Journal, Vol. 3, Issue. 2, p. 513.

Wu, Jichun and Hu, Bill 2004. Computational Methods in Water Resources: Volume 1. Vol. 55, Issue. , p. 705.

Sanchez-Vila, Xavier and Guadagnini, Alberto 2005. Travel time and trajectory moments of conservative solutes in three dimensional heterogeneous porous media under mean uniform flow. Advances in Water Resources, Vol. 28, Issue. 5, p. 429.

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Relative dispersion for solute flux in aquifers

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