Strong variation in weathering of layered rock maintains hillslope‐scale strength under high precipitation |
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| Authors: | Jennifer Von Voigtlander Marin K Clark Dimitrios Zekkos William W Greenwood Suzanne P Anderson Robert S Anderson Jonathan W Godt |
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| Affiliation: | 1. Department of Earth and Environmental Sciences, University of Michigan, Ann Arbor, MI, USA;2. Schlumberger Limited, Houston, TX, USA;3. Department of Civil and Environmental Engineering, University of Michigan, Ann Arbor, MI, USA;4. Department of Geography and INSTAAR, University of Colorado, Boulder, CO, USA;5. Department of Geological Sciences and INSTAAR, University of Colorado, Boulder, CO, USA;6. Natural Hazards Mission Area, Landslide Hazards Program, US Geological Survey, Denver, CO, USA |
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| Abstract: | The evolution of volcanic landscapes and their landslide potential are both dependent upon the weathering of layered volcanic rock sequences. We characterize critical zone structure using shallow seismic Vp and Vs profiles and vertical exposures of rock across a basaltic climosequence on Kohala peninsula, Hawai’i, and exploit the dramatic gradient in mean annual precipitation (MAP) across the peninsula as a proxy for weathering intensity. Seismic velocity increases rapidly with depth and the velocity–depth gradient is uniform across three sites with 500–600 mm/yr MAP, where the transition to unaltered bedrock occurs at a depth of 4 to 10 m. In contrast, velocity increases with depth less rapidly at wetter sites, but this gradient remains constant across increasing MAP from 1000 to 3000 mm/yr and the transition to unaltered bedrock is near the maximum depth of investigation (15–25 m). In detail, the profiles of seismic velocity and of weathering at wet sites are nowhere monotonic functions of depth. The uniform average velocity gradient and the greater depths of low velocities may be explained by the averaging of velocities over intercalated highly weathered sites with less weathered layers at sites where MAP > 1000 mm/yr. Hence, the main effect of climate is not the progressive deepening of a near‐surface altered layer, but rather the rapid weathering of high permeability zones within rock subjected to precipitation greater than ~1000 mm/yr. Although weathering suggests mechanical weakening, the nearly horizontal orientation of alternating weathered and unweathered horizons with respect to topography also plays a role in the slope stability of these heterogeneous rock masses. We speculate that where steep, rapidly evolving hillslopes exist, the sub‐horizontal orientation of weak/strong horizons allows such sites to remain nearly as strong as their less weathered counterparts at drier sites, as is exemplified by the 50°–60° slopes maintained in the amphitheater canyons on the northwest flank of the island. Copyright © 2017 John Wiley & Sons, Ltd. |
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| Keywords: | critical zone regolith formation shallow seismic profiles slope stability Hawai’ i basalt weathering |
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