The topographic signature of a major typhoon

In August 2009, the typhoon Morakot, characterized by a cumulative rainfall up to 2884 mm in about three days, triggered thousands of landslides in Taiwan. The availability of LiDAR surveys before (2005) and after (2010) this event offers a unique opportunity to investigate the topographic signatures of a major typhoon. The analysis considers the comparison of slope–area relationships derived by LiDAR digital terrain models (DTMs). This approach has been successfully used to distinguish hillslope from channelized processes, as a basis to develop landscape evolution models and theories, and understand the linkages between landscape morphology and tectonics, climate, and geology. We considered six catchments affected by a different degree of erosion: three affected by shallow and deep‐seated landslides, and three not affected by erosion. For each of these catchments, 2 m DTMs were derived from LiDAR data. The scaling regimes of local slope versus drainage area suggested that for the catchments affected by landslides: (i) the hillslope‐to‐valley transitions morphology, for a given value of drainage area, is shifted towards higher value of slopes, thus indicating a likely migration of the channelized processes and erosion toward the catchment boundary (the catchment head becomes steeper because of erosion); (ii) the topographic gradient along valley profiles tends to decrease progressively (the valley profile becomes gentler because of sediment deposition after the typhoon). The catchments without any landslides present a statistically indistinguishable slope–area scaling regime. These results are interesting since for the first time, using multi‐temporal high‐resolution topography derived by LiDAR, we demonstrated that a single climate event is able to cause significant major geomorphic changes on the landscape, detectable using slope–area scaling analysis. This provides new insights about landscape evolution under major climate forcing. Copyright © 2015 John Wiley & Sons, Ltd.

[1]  R. Sibson,et al.  A brief description of natural neighbor interpolation , 1981 .

[2]  David G. Tarboton,et al.  The analysis of river basins and channel networks using digital terrain data , 1989 .

[3]  E. Foufoula‐Georgiou,et al.  Channel network source representation using digital elevation models , 1993 .

[4]  Garry R. Willgoose,et al.  A statistic for testing the elevation characteristics of landscape simulation models , 1994 .

[5]  R. Bras,et al.  Scaling regimes of local slope versus contributing area in digital elevation models , 1995 .

[6]  D. Tarboton A new method for the determination of flow directions and upslope areas in grid digital elevation models , 1997 .

[7]  Gregory E. Tucker,et al.  Hillslope processes, drainage density, and landscape morphology , 1998 .

[8]  D. Montgomery Slope Distributions, Threshold Hillslopes, and Steady-state Topography , 2001 .

[9]  William E. Dietrich,et al.  Valley incision by debris flows: Evidence of a topographic signature , 2003 .

[10]  R. Bras,et al.  Vegetation-modulated landscape evolution: Effects of vegetation on landscape processes, drainage density, and topography , 2004 .

[11]  Jan Nyssen,et al.  Use of LIDAR‐derived images for mapping old landslides under forest , 2007 .

[12]  J. Roering,et al.  Automated landslide mapping using spectral analysis and high-resolution topographic data: Puget Sound lowlands, Washington, and Portland Hills, Oregon , 2008 .

[13]  George E. Hilley,et al.  Geomorphic response to uplift along the Dragon's Back pressure ridge, Carrizo Plain, California , 2008 .

[14]  Paolo Tarolli,et al.  Hillslope-to-valley transition morphology: new opportunities from high resolution DTMs. , 2009 .

[15]  P. Tarolli,et al.  Geomorphic features extraction from high-resolution topography: landslide crowns and bank erosion , 2012, Natural Hazards.

[16]  P. Tarolli,et al.  Suitability of LiDAR point density and derived landform curvature maps for channel network extraction , 2010 .

[17]  C. Tsou,et al.  Catastrophic landslide induced by Typhoon Morakot, Shiaolin, Taiwan , 2011 .

[18]  Chjeng-Lun Shieh,et al.  Landslides triggered by the 7 August 2009 Typhoon Morakot in southern Taiwan , 2011 .

[19]  O. Sass,et al.  Combining airborne and terrestrial laser scanning for quantifying erosion and deposition by a debris flow event , 2012 .

[20]  Alan W. Rempel,et al.  Topographic signatures and a general transport law for deep‐seated landslides in a landscape evolution model , 2013 .

[21]  P. Tarolli,et al.  Recognition of large scale deep-seated landslides in forest areas of Taiwan using high resolution topography , 2013 .

[22]  Colin P. Stark,et al.  Application of a multi‐temporal, LiDAR‐derived, digital terrain model in a landslide‐volume estimation , 2013 .

[23]  P. Tarolli High-resolution topography for understanding Earth surface processes: Opportunities and challenges , 2014 .