Geophysical survey method: Gradient Resistivity Profiling
Gradient resistivity profiling for groundwater surveys in diverse geological terrains involves adapting the method to varying subsurface conditions. Here’s how it can be applied across different geological settings.
1. Sedimentary Basins:
• In areas with sedimentary rocks, resistivity profiling helps identify layers with different porosities and permeability.
• Sandstone layers might indicate potential aquifers, while clay-rich layers may act as confining units
2. Crystalline Terrains:
• In regions with crystalline rocks, resistivity variations can reveal fractured zones that may serve as pathways for groundwater flow.
• Contrasting resistivity values between granite and fractured zones aids in mapping potential water-bearing fractures.
3. Karst Landscapes:
• In karst terrains, where soluble rocks like limestone are prevalent, resistivity profiling assists in locating conduits and cavities formed by dissolution.
• High resistivity might indicate less-permeable rock, while low resistivity may suggest water-filled voids.
4. Alluvial Plains:
• In areas with alluvial deposits, resistivity profiling is crucial for mapping the distribution of coarse and fine-grained sediments.
• Variation in resistivity can help delineate potential channels and floodplain aquifers.
5. Volcanic Regions:
• Resistivity surveys in volcanic terrains aid in identifying layers with varying degrees of water saturation.
• Porous volcanic deposits may exhibit lower resistivity, indicating potential groundwater reservoirs.
6. Fault Zones:
• Resistivity profiling across fault zones helps characterize the impact of faults on groundwater movement.
• Contrasts in resistivity on either side of a fault can indicate potential barriers or conduits for groundwater flow.
7. Coastal Areas:
• In coastal regions, resistivity profiling is useful for understanding the interface between fresh and saline water.
• Varying resistivity values can help delineate the extent of saltwater intrusion into aquifers.
8. Mountainous Regions:
• In mountainous terrains, resistivity profiling aids in assessing the depth and continuity of fractured rock layers.
• Steep topography may influence resistivity values due to variations in lithology and weathering.
Adapting the gradient resistivity profiling method to different geological contexts allows for a comprehensive understanding of subsurface conditions, aiding in effective groundwater resource management and exploration strategies tailored to each terrain’s unique characteristics.