GSA Annual Meeting in Seattle, Washington, USA - 2017

Paper No. 246-14
Presentation Time: 5:10 PM

LANDSLIDES CONTROL THE SPATIAL AND TEMPORAL VARIATION OF CHANNEL MORPHOLOGY IN SOUTHERN TAIWAN: IMPLICATIONS FOR LANDSCAPE EVOLUTION IN STEEP, TECTONICALLY ACTIVE LANDSCAPES


YANITES, Brian J.1, BREGY, Josh2, CARLSON, Grace1, CATALDO, Kirstyn1, HOLAHAN, Margaret1, JOHNSTON, Graham H.1, MITCHELL, Nathaniel1, NELSON, Amelia1, VALENZA, Jeffrey1 and WANKER, Matthew1, (1)Department of Earth and Atmospheric Sciences, Indiana University, 1001 East 10th Street, Bloomington, IN 47405, (2)Bloomington, IN 47405; Geography, Indiana University, 1001 East 10th Street, Bloomington, IN 47405, byanites@indiana.edu

Intense precipitation or seismic events can generate clustered mass movement processes across a landscape. These rare events have significant impacts on the landscape, however, the rarity of such events leads to uncertainty in how these events impact the entire geomorphic system over a range of timescales. Taiwan is a steep, seismically active region and is highly prone to landslide and debris flows, especially when exposed to heavy rainfall events. Typhoon Morakot made landfall in Taiwan in August of 2009, delivering record-breaking rainfall and inducing more than 22,000 landslides in southern Taiwan. The topographic gradient in southern Taiwan leads to spatial variability in landslide susceptibility providing an opportunity to infer the long-term impact of landslides on channel morphology. The availability of pre and post typhoon imagery allows a quantitative reconstruction on the propagating impact of this event on channel width. The pre and post typhoon patterns of channel width to river and hillslope gradients in 20 basins in the study area reveal the importance of cascading hazards from landslides on landscape evolution. Prior to Typhoon Morakot, the river channels in the central part of the study area were about 3–10 times wider than the channels in the south. Aggradation and widening was also a maximum in these basins where hillslope gradients and channel steepness is high. The results further show that the narrowest channels are located where channel steepness is the lowest, an observation inconsistent with a detachment-limited model for river evolution. We infer this pattern is indicative of a strong role of sediment supply, and associated landslide events, on long-term channel evolution. These findings have implications across a range of spatial and temporal scales including understanding the cascade of hazards in steep landscapes and geomorphic interpretation of channel morphology in tectonically active landscapes.