Water storage mapping of pyroclastic covers through electrical resistivity measurements

Water storage mapping of pyroclastic covers through electrical resistivity measurements

The knowledge of the geological setting of pyroclastic covers and their water content distribution represents crucial information for stability analyses of slopes potentially subject to debris-flow phenomena. The study we here present would provide a contribution to this issue by means of an approac...

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Bibliographic Details
Published in:Journal of applied geophysics Vol. 75; no. 2; pp. 196 - 202
Main Authors: Di Maio, R., Piegari, E.
Format: Journal Article
Language:English
Published: Oxford Elsevier B.V 01-10-2011
Elsevier
Subjects:
Applied geophysics
Earth sciences
Earth, ocean, space
ERT surveys
Exact sciences and technology
Internal geophysics
Laboratory resistivity characterization
Pyroclastic covers
Water storage mapping
Southern Europe
Italy
Campania Italy
Europe
Italy, Campania
Laboratory resistivity characterization
Pyroclastic covers
Water storage mapping
ERT surveys
mountains
rainfall
time variations
springs
surveys
debris flows
slopes
ERTS
depth
water storage
landslides
water content
soils
electrical resistivity
stability
high resolution
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Summary:The knowledge of the geological setting of pyroclastic covers and their water content distribution represents crucial information for stability analyses of slopes potentially subject to debris-flow phenomena. The study we here present would provide a contribution to this issue by means of an approach based on electrical resistivity measurements. Specifically, we describe the results of high-resolution 2D resistivity surveys carried out in a test area on Sarno Mountains (Campania Region – Southern Italy), where shallow landslides involving pyroclastic soils periodically occur triggered by critical rainfall events. We discuss the results in relation to the geology of the area in order to locate characteristic horizons of pyroclastic soils below the ground surface. Then, on the basis of a laboratory characterization of pyroclastic samples collected from the same test area at representative depths, we provide an estimation of the soil water content distribution in the field. Finally, we analyze temporal variations of the soil water content distribution by comparing the data of two surveys carried out in the autumnal and spring seasons, respectively. ► Water is the main driver of pyroclastic debris-flow phenomena. ► We examine changes of soil water content in the field using electrical resistivity tomography. ► Empirical relationships between soil resistivity and effective saturation are found. ► Geoelectric monitoring can identify the thickness of pyroclastic layers in saturated condition.
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ISSN:0926-9851
1879-1859
DOI:10.1016/j.jappgeo.2011.07.009