Groundwater exploration with the Magnetic Resonance Sounding method

J Bernard; A Legchenko

doi:10.1071/ASEG2003ab013

ISSN: 2202-0586
E-ISSN:

oa Groundwater exploration with the Magnetic Resonance Sounding method
Authors J Bernard^a and A Legchenko^b
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^a IRIS Instruments, , France, [email protected] ^b BRGM, , France, [email protected]
Publisher: Australian Society of Exploration Geophysicists
Source: ASEG Extended Abstracts, Volume 2003, Issue ASEG2003 - 16th Geophysical Conference, Aug 2003, p. 1 - 5
DOI: https://doi.org/10.1071/ASEG2003ab013
- Published online: 01 Aug 2003

Abstract

The Magnetic Resonance Sounding method (MRS) has been used in the past years with success in various geological and geographical contexts for groundwater surveys. This method has indeed the ability of directly detecting the presence of water through the excitation of the hydrogen protons of water molecules.

The frequency to which the H protons react depends on the magnitude of the Earth magnetic field, while the intensity of the excitation determines the depth of investigation. The amplitude of the magnetic field generated in return by the water of a layer is proportional to the porosity of this layer, and the time constant of the relaxation curve is linked to the mean pore size of the material, that is to say tightly related to its permeability.

A loop laid on the surface of the ground is used for both transmitting the excitation pulse and measuring the response of the H protons. The linear relation between the measured signal and the layer porosity permits to interpret the ID sounding as soon as the readings have been collected in the field.

The main applications of this method concern the determination of the water level and of the total quantity of water available down to 100 to 150 m depths. Magnetic Resonance Soundings can also help to select the best place for drilling, to predict a yield using a calibration, and to determine the geometry of an aquifer layer for hydrogeological modelling

A set of field examples acquired in various countries (Africa, Asia, Europe) points out both the advantages and the limitations of this method and suggests the place it should take among other geophysical methods in the methodology of groundwater investigations.

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2003-08-01

2026-01-15

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References

Legchenko, A., Shushakov, O., Perrin, J., Portselan, A., 1995, Noninvasive NMR study of subsurface aquifers in France, SEG Houston Conference abstract
Legchenko, A., Baltassat, J.M., Martin, C, Robain, H., Vouillamoz, J.M., 2002, Magnetic resonance sounding applied to catchment study, EEGS Meeting, Aveiro, 41-44
Roy, J., Lubczynski, M.W., 2000, The MRS technique for groundwater resources evaluation - test results from selected sites in Southern Africa, IAH-2000 Proceedings, Cape Town
Semenov, A.G., 1987, NMR Hydroscope for water prospecting, Proceedings of the seminar on Geotomography: Indian Geophysical Union, Hyderabad, 66-67
Schirov, M., Legchenko, A., Creer, G., 1991, A new direct non-invasive groundwater detection technology for Australia, Exploration Geophysics 22, 333-338
Valla, P., Yaramanci, U., 2002, Surface Nuclear Magnetic Resonance : What is possible ?, Special issue of the Journal of Applied Geophysics, volume 50, 230 pages
Varian, R.H., 1962, Ground liquid prospecting method and apparatus, US Patent, 3019383
Yaramanci, U., Lange, G., Knodel, K., 1999, Surface NMR within a geophysical study of an aquifer at Haldensleben (Germany), Geophysical Prospecting, 47, 923-943
Yulin, P., Le, W., 1999, Detecting of karst water in China with NMR method, CT theory and applicatios, vol 8 n°3

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Article Type: Research Article

Keyword(s): groundwater; Magnetic Resonance Sounding; NMR; permeability; porosity

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