Imaging artificial salt water infiltration using electrical resistivity tomography constrained by geostatistical data

[en] Electrical resistivity tomography is a well-known technique to monitor fresh-salt water transitions. In such environments, boreholes are often used to validate geophysical results but rarely used to constrain the geoelectrical inversion. To estimate the extent of salt water infiltration in the dune area of a Natural Reserve (Westhoek, Belgium), electrical resistivity tomography profiles were carried out together with borehole electromagnetic measurements. The latter were used to calculate a vertical variogram, representative of the study site. Then, a geostatistical constraint, in the form of an a priori model covariance matrix based on the variogram, was imposed as regularization to solve the electrical inverse problem. Inversion results enabled to determine the extension of the salt water plume laterally and at depth, but also to estimate the total dissolved solid content within the plume. These results are in agreement with the hydrogeological data of the site. A comparison with borehole data showed that the inversion results with geostatistical constraints are much more representative of the seawater body (in terms of total dissolved solids, extension and height) than results using standard smoothness-constrained inversion. The field results obtained for the Westhoek site emphasize the need to go beyond standard smoothness-constrained images and to use available borehole data as prior information to constrain the inversion.

Disciplines :

Géologie, ingénierie du pétrole & des mines

Auteur, co-auteur :

Hermans, Thomas ; Université de Liège - ULiège > Département Argenco : Secteur GEO3 > Géophysique appliquée

Vandenbohede, Alexander; Universiteit Gent - Ugent > Geology and Soil Science > Groundwater modelling

Lebbe, Luc; Universiteit Gent - Ugent > Geology and Soil Science > Groundwater Modelling

Martin, Roland; University of Bonn > Geodynamics and Geophysics

Kemna, Andreas; University of Bonn > Geodynamics and Geophysics

Beaujean, Jean ; Université de Liège - ULiège > Département Argenco : Secteur GEO3 > Géophysique appliquée

Nguyen, Frédéric ; Université de Liège - ULiège > Département Argenco : Secteur GEO3 > Géophysique appliquée

Langue du document :

Anglais

Titre :

Imaging artificial salt water infiltration using electrical resistivity tomography constrained by geostatistical data

Titre traduit :

[fr] Imagerie d'une infiltration d'eau salée par tomographie de résistivité électrique contrainte par des données géostatistiques

Date de publication/diffusion :

mai 2012

Titre du périodique :

Journal of Hydrology

ISSN :

0022-1694

eISSN :

1879-2707

Maison d'édition :

Elsevier Science

Volume/Tome :

438-439

Pagination :

168-180

Peer reviewed :

Peer reviewed vérifié par ORBi

Organisme subsidiant :

F.R.S.-FNRS - Fonds de la Recherche Scientifique [BE]

Commentaire :

Selected by Earth Emphasis as special interest to the progress in the Earth Sciences field http://earthemphasis.com/

Disponible sur ORBi :

depuis le 16 mars 2012

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Bibliographie

Amidu S.A., Dunbar J.A. An evaluation of the electrical-resistivity method for water-reservoir salinity studies. Geophysics 2008, 73(4):G39-G49. 10.1190/1.2938994.
Archie G.E. The electrical resistivity log as an aid in determining some reservoir characteristics. Trans. AIME 1942, 146:54-62.
Carter E.S., White S.M., Wilson A.M. Variation in groundwater salinity in a tidal salt marsh basin, North Inlet Estuary, South Carolina. Estuar. Coast. Shelf Sci. 2008, 76:543-552. 10.1016/j.ecss.2007.07.049.
Cassiani G., Böhm G., Vesnaver A., Nicolich R. A geostatistical framework for incorporating seismic tomography auxiliary data into hydraulic conductivity estimation. J. Hydrol. 1998, 29(1-2):58-74.
Chasseriau P., Chouteau M. 3D gravity inversion using a model of parameter covariance. J. Appl. Geophys. 2003, 52:59-74.
Constable S.C., Parker R.L., Constable C.G. Occam's inversion: a practical algorithm for generating smooth models from electromagnetic sounding data. Geophysics 1987, 52(3):289-300.
Dahlin T., Zhou B. A numerical comparison of 2D resistivity imaging with ten electrode arrays. Geophys. Prospect. 2004, 52:379-398. 10.1111/gpr.2004.52.issue-5.
Day-Lewis F.D., Lane J.W. Assessing the resolution-dependent utility of tomograms for geostatistics. Geophys. Res. Lett. 2004, 31:L07503. 10.1029/2004GL019617.
De Franco R., Biella G., Tosi L., Teatini P., Lozej A., Chiozzotto B., Giada M., Rizzetto F., Claude C., Mayer A., Bassan V., Gasparetto-Stori G. Monitoring the saltwater intrusion by time lapse electrical resistivity tomography: the Chioggia test site (Venice Lagoon, Italy). J. Appl. Geophys. 2009, 69:117-130. 10.1016/j.jappgeo.2009.08.004.
deGroot-Hedlin C., Constable S. Occam's inversion to generate smooth, two dimensional models from magnetotelluric data. Geophysics 1990, 55:1613-1624.
Deutsch C.V., Journel A.G. GSLIB: Geostatistical Software Library: And User's Guide 1998, Oxford University Press, New York, NY, 369 pp. second ed.
Goldman, M., Kafri, U., 2006. Hydrogeophysical applications in coastal aquifers. In: Vereecken, H., Binley, A., Cassiani, G., Revil, A., Titov, K. (Eds.), Applied Hydrogeophysics. Nato Science Series, Serie IV, Earth and Environmental Sciences, 71, Springer, Dordrecht, 233-254.
Guardiano F.B., Srivatsava R.M. Multivariate geostatistics: beyond bivariate moments. Geostatistics Troia '92 1993, 133-144. Kluver Academic Publishers, Dordrecht. A. Soares (Ed.).
Hansen P.C. Rank-deficient and Discrete Ill-posed Problems: Numerical Aspects of Linear Inversion 1998, SIAM, Philadelphia.
Hansen T.M., Journel A.G., Tarantola A., Mosegaard K. Linear inverse Gaussian theory and geostatistics. Geophysics 2006, 71(6):R101-R111.
Henderson, R.D., Day-Lewis, F.D., Abarca, E., Harvey, C.F., Karam, H.N., Liu, L., Lane, J.W. Jr., 2010, Marine Electrical Resistivity Imaging of Submarine Groundwater Discharge: Sensitivity Analysis and Application in Waquoit Bay, Massachussets, USA.
Isaaks E.H., Srivastava R.M. Applied Geostatistics 1989, Oxford University Press, New-York, 561 pp.
Johnson T.C., Routh P.S., Clemo T., Barrash W., Clement W.P. Incorporating geostatistical constraints in nonlinear inversion problems. Water Resour. Res. 2007, 43:W10422. 10.1029/2006WR005185.
Journel A.G., Huijbregts C.J. Mining Geostatistics 1978, Academic Press, London, New York.
Kemna, A., 2000. Tomographic Inversion of Complex Resistivity - Theory and Application. Ph.D. Thesis, Ruhr-University of Bochum.
LaBrecque D.J., Miletto M., Daily W., Ramirez A., Owen E. The effects of noise on Occam's inversion of resistivity tomography data. Geophysics 1996, 61(2):538-548.
Lebbe, L., 1978. Hydrogeologie van het duingebied ten westen van De Panne. Ph.D. Thesis, University of Ghent, Ghent, 164pp, unpublished.
Lebbe L. Parameter identification in fresh-saltwater flow based on borehole resistivities and freshwater head data. Adv. Water Resour. 1999, 22(8):791-806.
Linde N., Binley A., Tryggvason A., Petersen L.B., Revil A. Improved hydrogeophysical characterization using joint inversion of cross-hole electrical resistance and ground-penetrating radar traveltime data. Water Resour. Res. 2006, 42:W12404. 10.1029/2006WR005131.
Martin, R., Kemna, A., Hermans, T., Nguyen, F., Vandenbohede, A., Lebbe, L., 2010. Using geostatistical constraints in electrical imaging for improved reservoir characterization. Abstract H23L-06 Presented at 2010 Fall Meeting, AGU, San Francisco, Calif., 13-17 December.
Martínez J., Benavente J., García-Aróstegui J.L., Hidalgo M.C., Rey J. Contribution of electrical resistivity tomography to the study of detrital aquifers affected by seawater intrusion-extrusion effects: the river Vélez delta (Vélez-Málaga, southern Spain). Eng. Geol. 2009, 108:161-168.
Maurer H., Holliger K., Boerner D.E. Stochastic regularization: smoothness or similarity?. Geophys. Res. Lett. 1998, 25:2889-2892.
McNeill, J.D., 1986. Geonics EM39 Borehole Conductivity Meter - Theory of Operation. Geonics Limited Technical Note TN-20.
Nguyen F., Kemna A., Antonsson A., Engesgaard P., Kuras O., Ogilvy R., Gisbert J., Jorreto S., Pulido-Bosch A. Characterization of seawater intrusion using 2D electrical Imaging. Near Surf. Geophys. 2009, 7:377-390. 10.3997/1873-0604.2009025.
Parasnis D.S. Reciprocity theorems in geoelectric and geoelectromagnetic work. Geo-exploration 1988, 25:177-198.
Pilkington M.M., Todoeschuck J.P. Naturally smooth inversion with a priori information from well logs. Geophysics 1991, 56:1811-1818.
Robert T., Dassargues A., Brouyère S., Kaufmann O., Hallet V., Nguyen F. Assessing the contribution of electrical resistivity tomography (ERT) and self-potential (SP) methods for a water well drilling program in fractured/karstified limestones. J. Appl. Geophys. 2011, 75:42-53.
Slater L., Binley A.M., Daily W., Johnson R. Cross-hole electrical imaging of a controlled saline tracer injection. J. Appl. Geophys. 2000, 44:85-102.
Smith J.T., Booker J.R. Magnetotelluric inversion for minimum structure. Geophysics 1988, 53:1565-1576.
Strebelle, S., Payrazyan, K., Caers, J., 2002. Modeling of a deepwater turbidite reservoirs conditional to seismic data using multiple-point geostatistics. Paper Presented at SPE Annual Technical Conference and Exhibition, Society of Petroleum Engineers Inc., San Antonio, Texas.
Tarantola A., Valette B. Generalized non-linear problems solved using the least-squares criterion. Rev. Geophys. Space Phys. 1982, 20:219-232.
Tarantola A. Inverse Problem Theory 1987, Elsevier, Amsterdam.
The Earth Institute - Columbia University, 2006. It's 2025. Where Do Most People Live? Columbia University, New-York. http://www.earth.columbia.edu/news/2006/story07-11-06.php.
Tikhonov A.N., Arsenin V.A. Solution of Ill-posed Problems 1977, Winston & Sons, Washington.
Vandenbohede A., Lebbe L. Occurrence of salt water above fresh water in dynamic equilibrium in coastal groundwater flow systems. Hydrol. J. 2006, 14(4):462-472.
Vandenbohede A., Lebbe L., Gysens S., Delecluyse K., DeWolf P. Salt water infiltration in two artificial sea inlets in the Belgian dune area. J. Hydrol. 2008, 360:77-86.
Van Meir N., Lebbe L. Deriving TDS values in coarse sediments from long normal and electromagnetic logs. Ground Water 2003, 41(1):33-40.
Verwaest, T., De Wolf, P., Herrier, J.-L., Leten, M., 2005. Windows in the dunes - the creation of sea inlets in the nature reserve de Westhoek in de Panne. In: Herrier, J.-L., Mees, J., Salman, A., Seys, J., Van Nieuwenhuyse, H., Dobbelare, I. (Eds.), Proceedings " Dunes end Estuaries 2005" - International Conference on Nature Restoration Practices in European Coastal Habitats, Koksijde, Belgium, 19-23 September 2005, vol. 19. VLIZ Special Publication, 433-439.
Yang, X., LaBrecque, D.J., 1998. Stochastic inversion of 3D ERT data. In: Symposium on the Application of Geophysics to Engineering and Environmental Problems, vol. 11, EEGS, pp. 221-228.
Yeh T.-C.J., Jin M., Hanna S. An iterative stochastic inverse method: conditional effective transmissivity and hydraulic head fields. Water Resour. Res. 1996, 32(1):85-92.
Yeh T.-C.J., Liu S. Hydraulic tomography: development of a new aquifer test method. Water Resour. Res. 2000, 36(8):2095-2105.
Yeh T.-C.J., Liu S., Glass R.J., Baker K., Brainard J.R., Alumbaugh D., LaBrecque D. A geostatistically based inverse model for electrical resistivity surveys and its applications to vadose zone hydrology. Water Resour. Res. 2002, 38(12). 10.1029/2001WR001204.
Yeh, T.-C. J., Zhu, J., Englert, A., Guzman, A., Flaherty, S., 2006. A successive linear estimator for electrical resistivity tomography. In: Vereecken, H., Binley, A., Cassiani, G., Revil, A., Titov, K. (Eds.), Applied Hydrogeophysics. NATO Science Series, Springer, pp. 383.