EP53B-1030
Influence of topography on debris flow development in Ichino-sawa subwatershed of Ohya-kuzure landslide, Japan

Friday, 18 December 2015
Poster Hall (Moscone South)
Haruka Tsunetaka1, Norifumi Hotta1, Fumitoshi Imaizumi2 and Yuichi S. Hayakawa3, (1)University of Tsukuba, Life and Environmental Sciences, Ibaraki, Japan, (2)Shizuoka University, Graduate School of Agriculture, Shizuoka, Japan, (3)The University of Tokyo, Center of Spatial Information Science, Chiba, Japan
Abstract:
Large sediment movements, such as deep-seated landslides, produce unstable sediment over the long term. Most of the unstable sediment in a mountain torrent is discharged via the development of debris flows through entrainment. Consequently, after a large sediment movement, debris flows have long-term effects on the watershed regime. However, the development of debris flows in mountain torrents is poorly understood, since the topography is more complicated than downstream. We compared temporal changes in topography to examine how topography affects the development of flows. The study site was the Ichino-sawa subwatershed in the Ohya-kuzure landslide, Japan. Unstable sediment has been produced continuously since the landslide occurred in 1707. Several topographic surveys using a terrestrial laser scanner (TLS) and aerial shoots by an unmanned aerial vehicle (UAV) were performed between November 2011 (TLS) or November 2014 (UAV) and August 2015. High-resolution digital elevation models were created from the TLS and UAV results to detect temporal topographic changes. Debris flow occurrences and rainfall were also monitored using interval cameras and rain gauges. Downstream, the deposit depth decreased after the debris flows. Upstream, more complex changes were detected due to surges in the debris flows, which not only induced entrainment, but were also deposited in the valley floor. Furthermore, sediment was supplied from the stream bank during the debris flows. Consequently, several debris flows of different magnitudes were observed, although the rainfall conditions did not differ significantly. The results imply that the magnitude of the debris flows was affected by successive sediment movement resulting from the changing of the topographic conditions.