Spatio-temporal variations in floodplain soil/sediment conductivity: Great Darling Anabranch

Kevin Cahill; Tim Munday; Tania Abdat

doi:10.1071/ASEG2013ab157

ISSN: 2202-0586
E-ISSN:

oa Spatio-temporal variations in floodplain soil/sediment conductivity: Great Darling Anabranch
Authors Kevin Cahill^a, Tim Munday^b and Tania Abdat^c
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^a CSIRO, 26 Dick Perry Avenue, Kensington, , WA, 6151, [email protected] ^b CSIRO, 26 Dick Perry Avenue, Kensington, , WA, 6151, [email protected] ^c CSIRO, 26 Dick Perry Avenue, Kensington, , WA, 6151, [email protected]
Publisher: Australian Society of Exploration Geophysicists
Source: ASEG Extended Abstracts, Volume 2013, Issue ASEG2013 - 23rd Geophysical Conference, Dec 2013, p. 1 - 3
DOI: https://doi.org/10.1071/ASEG2013ab157
- Published online: 01 Dec 2013

Abstract

Spatio-temporal information on the distribution of salt in floodplain soils and groundwater is integral to effective floodplain management strategies along the Great Darling Anabranch in NSW. Geophysical technologies have the potential to provide detailed spatial information on the variability of salt stored in the near surface and for monitoring surface water -groundwater interactions across the floodplains, and in particular looking at the spatial controls on those processes. The research sought to examine the role of hydrogeophysical methods in monitoring changes in floodplain sediment condition, linked to ecological investigations.

A two stage investigation, to examine the role of a low cost, near surface, geophysical method for monitoring changes across several sites located adjacent to the Anabranch. It represented a short term spatio-temporal investigation of inundation on salt in the floodplain.

Our results clearly show changes in the near-surface conductivity distribution at the sites surveyed. These changes are attributed to variations in the flows over the year, pumping of groundwater and changes in vegetation.

The survey shows that EM techniques are a useful tool in aiding our understanding of floodplain processes resulting from changes in flows along the Anabranch and can be applied in other floodplain environments as a low- cost survey to observe changes in conductivity in the near surface.

It is an effective method to monitor variations in conductivity in the floodplains due to changes in environmental flows and can aid in understanding changes in sediment conditions and be used to validate floodplain processes, contributing to ecological investigations of river floodplains.

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2026-01-23

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References

Berens, V., White, M.G., Souter, N.J., Jolly, I.D., Holland, K.L. McEwan, K.L., Hatch, M.A., Fitzpatrick, A.D. and Munday, T. J., 2007, Surface Water, Groundwater and Ecological Interactions along the RiverMurray. A Pilot Study of Management Initiatives at the Bookpurnong Floodplain, South Australia, Near Surface 2007 conference proceedings, Istanbul, Turkey.
Fitzpatrick, A.D., Cahill, K.J., Berens, V., Hatch, M.A., and Munday, T.J., 2007, Ground Electromagnetic Surveys: Chowilla Floodplain, South Australia. CSIRO EM Restricted Report No: P2007/565
McNeill, J.D., 1980, Electromagnetic Terrain Conductivity Measurements at Low Induction Numbers: Mississauga, Ontario, Canada, Geonics Ltd. Technical Note TN-6, 15 p.
Reid, J.E. and Howlett, A., 2001, Application of EM-31 terrain conductivity meter in highly-conductive regimes: Exploration Geophysics, 32, 219-224.
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Stewart, M.T., and R. Bretnall. 1986. Interpretation of VLF resistivity data for ground water contamination surveys. Ground Water Monitoring Review 6, no. 1: 71-75.
Williams B.G, Baker G.C, 1982 An electromagnetic induction technique for reconnaissance surveys of salinity hazards. Australian Journal of Soil Research 20, 107-118.
Williams B. G, and Hoey D., 1987 Electromagnetic induction to detect the spatial variability of the salt and clay contents of soils. Australian Journal of Soil Research 25, 21-27.

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Article Type: Research Article

Keyword(s): Darling River Anabranch; Electromagnetics; floodplains

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oa Spatio-temporal variations in floodplain soil/sediment conductivity: Great Darling Anabranch

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