Abstract
AbstractThe soils and underlying weathered carbonate rock in karstic regions play an important role in the infiltration, storage, and retention of water and nutrients. Because of significant heterogeneity of the karst, the use of individual geophysical techniques is often not sufficient for unambiguous assessment of the irregular distributions of soils and underlying fractures. In this study, ground penetrating radar (GPR) and electrical resistivity tomography (ERT) are jointly used with additional observations to delineate the shallow subsurface structure in two exposed profiles. The results show that ERT is effective for detecting the soil–rock interfaces, even for irregular terrain and fracture structures, such as a funnel‐shaped doline, as the soils and rocks show a large resistivity contrast. Although ERT may be able to sense the presence of extensive fracturing, it cannot detect individual small aperture fractures. Joint use of different frequencies of the GPR antenna (e.g., 100 and 500 MHz in this study) allowed the detection of most fractures at different depths in the study sites. However, forward modeling of typical weathered rock features illustrates that the GPR data cannot resolve any reflection signals of the vertical fractures, so the features of vertically enlarged fractures filled by soils cannot be seen from the GPR images. Moreover, large uncertainties of resistivity at the interface between soils or fractures and bedrock limit the identification of an irregularly distributed subsurface structure. Despite the limitations of individual techniques, the combination of ERT and GPR enhances the delineation of the soil–bedrock interface and identification of the fracture network, which can allow an enhanced geological interpretation of shallow subsurface features in the karst areas.
Highlights
Karst is an important landscape, which covers about 15% of the world’s land area or about 2.2 million km2 (Yuan & Cai, 1988). 25% of the global population fully or partially depends on water from karst aquifers (Ford & Williams, 2013)
Continuous karst areas in the world is located in Yunnan-Guizhou Plateau of southwest China, an area that has a population of 100 million
Capturing the shallow subsurface structures can improve our knowledge of the complex hydrodynamic functioning of both unsaturated and saturated zones (e.g. Bakalowicz, 1995; Ford & Williams, 2007; Goldscheider & Drew, 2007; Mangin, 1975; White, 2007)
Summary
Karst is an important landscape, which covers about 15% of the world’s land area or about 2.2 million km (Yuan & Cai, 1988). 25% of the global population fully or partially depends on water from karst aquifers (Ford & Williams, 2013). Karst is an important landscape, which covers about 15% of the world’s land area or about 2.2 million km (Yuan & Cai, 1988). 25% of the global population fully or partially depends on water from karst aquifers (Ford & Williams, 2013). Continuous karst areas in the world is located in Yunnan-Guizhou Plateau of southwest China, an area that has a population of 100 million. Carbonate rocks occupy 41% of the total area (730.6 103 km). Soils are generally 30-50 cm thick and are sporadically developed on carbonate rocks. The composition and structure of shallow subsurface soils and limestone fractures control infiltration and percolation, erosional rates and patterns in the landscape. Capturing the shallow subsurface structures can improve our knowledge of the complex hydrodynamic functioning of both unsaturated and saturated zones (e.g. Bakalowicz, 1995; Ford & Williams, 2007; Goldscheider & Drew, 2007; Mangin, 1975; White, 2007)
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