Testing the potential of geochemical techniques in identifying hydrological systems within landslides in partly weathered marls
Publication date
2004
Authors
Bogaard, T.A.
Buma, J.T.
Klawer, C.J.M.
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Document Type
Article
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(c) UU Universiteit Utrecht, 2004
Abstract
This paper’s objective is to determine how useful geochemistry can be in landslide investigations. More specifically, what
additional information can be gained by analysing the cation exchange capacity (CEC) and cation composition in respect to the
hydrological system of a landslide area in clayey material. Two cores from the Boulc–Mondore`s landslide (France) and one
core from the Alvera landslide (Italy) were analysed. The NH4Ac and NaCl laboratory techniques are tested. The geochemical
results are compared with the core descriptions and interpreted with respect to their usefulness. Both analysis techniques give
identical results for CEC, and are plausible on the basis of the available clay content information. The determination of the
exchangeable cations was more difficult, since part of the marls dissolved. With the ammonium-acetate method more of the
marls are dissolved than with the sodium-chloride method. The NaCl method is preferred for the determination of the cation
fractions at the complex, be it that this method has the disadvantage that the sodium fraction cannot be determined. To
overcome this problem, it is recommended to try other displacement fluids. In the Boulc–Mondore`s example, the subsurface
information that can be extracted from CEC analyses was presented. In the Boulc–Mondore`s cores deviant intervals of CEC
could be identified. These are interpreted as weathered layers (and preferential flow paths) that may develop or have already
developed into slip surfaces. The major problem of the CEC analyses was to explain the origin of the differences found in the
core samples. Both Alvera and Boulc–Mondore`s examples show transitions in cation composition with depth. It was shown
that the exchangeable caution fractions can be useful in locating boundaries between water types, especially the boundary
between the superficial, rain-fed hydrological system and the lower, regional groundwater system. This information may be
important for landslide interventions since the hydrological system and the origin of the water need to be known in detail. It is
also plausible that long-term predictions of slope stability may be improved by knowledge of the hydrogeochemical evolution
of clayey landslides. From the analysis, it is concluded that geochemistry is a potentially valuable technique for landslide
research, but it is recognized that a lot of work still has to be done before the technique can be applied in engineering practice
Keywords
Landslide, Geochemistry, Hydrology, Weathering