Advances in agrogeophysics: geophysical monitoring of the fresh–saline water interface in an agricultural field in the Belgian polders

Blanchy, Guillaume; Everaert, B.; Rodriguez, E.; Mehmandoostkotlar, A.; Caterina, David; Chambers, J.; Nguyen, Frédéric; Hermans, T.; De Smedt, P.; Huits, D.; Garré, S.

doi:10.5802/crgeos.291

Article (Scientific journals)

Advances in agrogeophysics: geophysical monitoring of the fresh–saline water interface in an agricultural field in the Belgian polders

Blanchy, Guillaume; Everaert, B.; Rodriguez, E. et al.

2025 • In Comptes Rendus. Geoscience, 357, p. 47 - 60

Peer Reviewed verified by ORBi

Permalink
https://hdl.handle.net/2268/334170

DOI
10.5802/crgeos.291

Files (1)Send to Details Statistics Bibliography Similar publications

Files

Full Text

CRGEOS_2025__357_G1_47_0.pdf

Publisher postprint (13.17 MB)

Download

All documents in ORBi are protected by a user license.

Send to

RIS BibTex APA Chicago Permalink X Linkedin

Details

Disciplines :

Geological, petroleum & mining engineering

Author, co-author :

Blanchy, Guillaume ; Université de Liège - ULiège > Urban and Environmental Engineering

Everaert, B.

Rodriguez, E.

Mehmandoostkotlar, A.

Caterina, David ; Université de Liège - ULiège > Urban and Environmental Engineering

Chambers, J.

Nguyen, Frédéric ; Université de Liège - ULiège > Département ArGEnCo > Géophysique appliquée

Hermans, T.

De Smedt, P.

Huits, D.

Garré, S.

Language :

English

Title :

Advances in agrogeophysics: geophysical monitoring of the fresh–saline water interface in an agricultural field in the Belgian polders

Publication date :

2025

Journal title :

Comptes Rendus. Geoscience

ISSN :

1631-0713

eISSN :

1778-7025

Volume :

357

Pages :

47 - 60

Peer reviewed :

Peer Reviewed verified by ORBi

Additional URL :

https://www.scopus.com/inward/record.uri?eid=2-s2.0-105004451638&doi=10.5802%2fcrgeos.291&partnerID=40&md5=05cb73e77ff61bacd1c07e849458d253

Available on ORBi :

since 08 July 2025

Statistics

Number of views

75 (2 by ULiège)

Number of downloads

53 (1 by ULiège)

More statistics

Scopus citations^®

Scopus citations^®
without self-citations

OpenCitations

OpenAlex citations

Bibliography

Archie, G. E., “The electrical resistivity log as an aid in determining some reservoir characteristics”, Trans. AIME 146 (1942), no. 01, pp. 54–62.
Ayars, J. E., E. W. Christen and J. W. Hornbuckle, “Controlled drainage for improved water management in arid regions irrigated agriculture”, Agric. Water Manag. 86 (2006), no. 1–2, pp. 128–139.
Binley, A. and L. Slater, Resistivity and Induced Polarization: Theory and Applications to the Near-Surface Earth, Cambridge University Press: Cambridge, 2020.
Blanchy, G., B. Everaert, E. L. Rodriguez Lache and A. Mehmandoost Kotlar, Advances in agrogeophysics: geophysical monitoring of the fresh–saline water interface in an agricultural field in the Belgian polders, 2025. Online at https: / / zenodo . org / records/15260574 (accessed on April 20, 2025).
Blanchy, G., S. Saneiyan, J. Boyd, P. McLachlan and A. Binley, “ResIPy, an intuitive open source software for complex geoelectrical inversion/modeling”, Comput. Geosci. 137 (2020), article no. 104423.
Castellano, M. J., S. V. Archontoulis, M. J. Helmers, H. J. Poffenbarger and J. Six, “Sustainable intensification of agricultural drainage”, Nat. Sustain. 2 (2019), no. 10, pp. 914–921.
Chambers, J., J. Holmes, J. Whiteley, et al., “Long-term geoelectrical monitoring of landslides in natural and engineered slopes”, Lead. Edge 41 (2022), no. 11, pp. 768–776.
Daliakopoulos, I. N., I. K. Tsanis, A. Koutroulis, N. N. Kourgialas, A. E. Varouchakis, G. P. Karatzas and C. J. Ritsema, “The threat of soil salinity: a European scale review”, Sci. Total Environ. 573 (2016), pp. 727–739.
De Breuck, W. and G. De Moor, “The evolution of the coastal aquifer of Belgium”, in Proceedings of the 4th Salt Water Intrusion Meeting, Ghent, 1974, pp. 158–172.
de Louw, P., Saline seepage in deltaic areas: Preferential groundwater discharge through boils and interactions between thin rainwater lenses and upward saline seepage, PhD thesis, Vrije Universiteit Amsterdam, 2013.
de Louw, P., E. van Baaren, V. Kaandorp, et al., TOPSOIL—GO-FRESH Vlaanderen Potenties om de zoetwaterbeschikbaarheid te verbeteren, Technical Report, 2019.
De Wit, J. A., J. C. Van Dam, G. A. P. H. Van Den Eertwegh, M. H. J. Van Huijgevoort, C. J. Ritsema and R. P. Bartholomeus, “Controlled drainage with subirrigation systems: Reduce water supply by automatic control”, Agric. Water Manag. 303 (2024), article no. 109022.
De Wit, J. A., M. H. J. Van Huijgevoort, J. C. Van Dam, G. A. P. H. Van Den Eertwegh, D. Van Deijl, C. J. Ritsema and R. P. Bartholomeus, “Hydrological consequences of controlled drainage with subirrigation”, J. Hydrol. 628 (2024), article no. 130432.
Deleersnyder, W., B. Maveau, T. Hermans and D. Dudal, “Flexible quasi-2D inversion of time-domain AEM data, using a wavelet-based complexity measure”, Geophys. J. Int. 233 (2023), no. 3, pp. 1847–1862.
Delsman, J., E. van Baaren, T. Vermaas, et al., TOPSOIL airborne EM kartering van zoet en zout grondwater in Vlaanderen (FRESHEM Vlaanderen), 2019. 11200306-00-BGS-0011. Deltares.
Delsman, J. R., E. S. van Baaren, B. Siemon, et al., “Large-scale, probabilistic salinity mapping using airborne electromagnetics for groundwater management in Zeeland, the Netherlands”, Environ. Res. Lett. 13 (2018), no. 8, article no. 084011.
Delsman, J. R., M. J. Waterloo, M. M. A. Groen, J. Groen and P. J. Stuyfzand, “Investigating summer flow paths in a Dutch agricultural field using high frequency direct measurements”, J. Hydrol. 519 (2014), pp. 3069–3085.
Dou, X., H. Shi, R. Li, Q. Miao, J. Yan and F. Tian, “Evaluating the effects of controlled drainage on nitrogen uptake, utilization, leaching, and loss in farmland soil”, Agronomy 13 (2023), no. 12, article no. 2936.
Eeman, S., Dynamics of rainwater lenses on upward seeping saline groundwater, PhD thesis, Wageningen University, 2017.
Elsen, F. and T. Coussement, Drainage + Peilgestuurde drainage als alternatief voor klassieke drainage, Technical Report, 2019.
Evans, R. O., R. Wayne Skaggs and J. Wendell Gilliam, “Controlled versus conventional drainage effects on water quality”, J. Irrig. Drain. Eng. 121 (1995), no. 4, pp. 271–276.
FAO, Global Status of Salt-Affected Soils, FAO: Rome, 2024. Online at https: / / openknowledge . fao . org / handle / 20 . 500 . 14283 / cd3044en (accessed on December 20, 2024).
Hanssens, D., Robust collection and processing of small loop frequency domain electromagnetic data, PhD thesis, Ghent University. Online at https: / / hdl. handle. net / 1854 / LU - 8675347 (accessed on July 18, 2024). ISBN: 9789463573542.
Hermans, T., A. Vandenbohede, L. Lebbe, R. Martin, A. Kemna, J. Beaujean and F. Nguyen, “Imaging artificial salt water infiltration using electrical resistivity tomography constrained by geostatistical data”, J. Hydrol. 438–439 (2012), pp. 168–180.
LaBrecque, D. J. and X. Yang, “Difference inversion of ERT data: a fast inversion method for 3-D in situ monitoring”, J. Environ. Eng. Geophys. 6 (2001), no. 2, pp. 83–89.
Ma, R., A. McBratney, B. Whelan, B. Minasny and M. Short, “Comparing temperature correction models for soil electrical conductivity measurement”, Precis. Agric. 12 (2011), no. 1, pp. 55–66.
Mitchell, M. E., T. Newcomer-Johnson, J. Christensen, W. Crumpton, B. Dyson, T. J. Canfield, M. Helmers and K. J. Forshay, “A review of ecosystem services from edge-of-field practices in tile-drained agricultural systems in the United States corn belt region”, J. Environ. Manag. 348 (2023), article no. 119220.
Neumann, B., A. T. Vafeidis, J. Zimmermann and R. J. Nicholls, “Future coastal population growth and exposure to sea-level rise and coastal flooding — a global assessment”, PLoS One 10 (2015), no. 3, article no. e0118571.
Paepen, M., K. Walraevens and T. Hermans, “Footprint of fresh submarine groundwater discharge in the Belgian coastal zone: an overview study”, Lead. Edge 42 (2023), no. 9, pp. 598–607.
Pauw, P. S., Field and model investigations of freshwater lenses in coastal aquifers, PhD thesis, Wageningen University, 2015.
Drainage Principles and Applications, 2nd (completely rev.) edition (Ritzema, H. P., ed.), Number 16 in ILRI Publication, ILRI: Wageningen, 1994.
Ritzema, H. P., “Drain for gain: managing salinity in irrigated lands—a review”, Agric. Water Manag. 176 (2016), pp. 18–28.
Rodriguez, E., G. Blanchy, A. Mehmandoostkotlar and S. Garré, “Performance of controlled drainage in tile-drained agricultural fields. An exploratory scenario analysis with the soil-plant model Swap”, Agric. Water Manag. (2024). (submitted).
Ronczka, M., T. Günther, M. Grinat and H. Wiederhold, “Monitoring freshwater–saltwater interfaces with SAMOS–installation effects on data and inversion”, Near Surf. Geophys. 18 (2020), no. 4, pp. 369–383.
Salla, A., H. Salo, M. Tähtikarhu, H. Marttila, M. Läpikivi, M. Liimatainen, T. Lötjönen and H. Koivusalo, “Simulating controlled drainage and hydrological connections in a cultivated peatland field”, Vadose Zone J. 23 (2024), no. 6, article no. e20387.
Vandenbohede, A., K. Hinsby, C. Courtens and L. Lebbe, “Flow and transport model of a polder area in the Belgian coastal plain: example of data integration”, Hydrogeol. J. 19 (2011), no. 8, pp. 1599–1615.
Vandenbohede, A., L. Lebbe, S. Gysens, K. Delecluyse and P. De-Wolf, “Salt water infiltration in two artificial sea inlets in the Belgian dune area”, J. Hydrol. 360 (2008), no. 1, pp. 77–86.
Velstra, J., J. Groen and K. De Jong, “Observations of salinity patterns in shallow groundwater and drainage water from agricultural land in the Northern part of the Netherlands”, Irrig. Drain. 60 (2011), no. S1, pp. 51–58.
Virtanen, P., R. Gommers, T. E. Oliphant, et al., “SciPy 1.0: fundamental algorithms for scientific computing in Python”, Nat. Meth. 17 (2020), no. 3, pp. 261–272.
Wang, Z., G. Shao, J. Lu, K. Zhang, Y. Gao and J. Ding, “Effects of controlled drainage on crop yield, drainage water quantity and quality: a meta-analysis”, Agric. Water Manag. 239 (2020), article no. 106253.
Waxman, M. H. and L. J. M. Smits, “Electrical conductivities in oil-bearing shaly sands”, Soc. Pet. Eng. J. 8 (1968), no. 02, pp. 107–122.
Wild, J., M. Kopecký, M. Macek, M. Šanda, J. Jankovec and T. Haase, “Climate at ecologically relevant scales: a new temperature and soil moisture logger for long-term microclimate measurement”, Agric. For. Meteorol. 268 (2019), pp. 40–47.
Youssef, M. A., J. Strock, E. Bagheri, et al., “Impact of controlled drainage on corn yield under varying precipitation patterns: a synthesis of studies across the U.S. Midwest and Southeast”, Agric. Water Manag. 275 (2023), article no. 107993.