This is just one of the graphs from the paper.\u00a0 It shows the landslide ratio – the proportion of the terrain that consists of active landslides – for a number of catchments in both northern and southern Taiwan each year from 2003 to 2012:<\/p>\n
![\"Taiwan](\"https:\/\/blogs.agu.org\/landslideblog\/files\/2017\/05\/17_05-Taiwan-1.jpg\")
Taiwan landslide hotspots: the landslide ration through time for northern and southern Taiwan, from Lin et al.<\/em> (2017).<\/a><\/p><\/div>\n .<\/p>\n Until 2008 the landslide ratio for both areas was roughly similar at around 0.5-2%. Southern Taiwan was slightly higher than northern Taiwan, perhaps, probably because the terrain in the south is more rugged.\u00a0 But a dramatic change occurred in southern Taiwan after 2008, with no corresponding effect in northern Taiwan.\u00a0 In 2009 the landslide ratio suddenly dramatically increased in the south.\u00a0 Thereafter the landslide ratios in southern Taiwan were much higher, although they also started to decline thereafter.<\/p>\n Taiwan landslide hotspots: damage from debris flows in the aftermath of typhoon Morakot<\/p><\/div>\n .<\/p>\n So what happened in 2009 in southern Taiwan?\u00a0 Quite simply this is the effect of the extraordinary Typhoon Morakot<\/a>, which brought vast amounts of rainfall to southern Taiwan, and triggered thousands of landslides<\/a>, including the dreadful Shiaolin event<\/a>.\u00a0 The paper shows very elegantly that these extreme events leave a long term legacy of increased landsliding for years afterwards.\u00a0 This effect is well documented for large earthquakes in mountain chains; this paper shows very nicely that there is a similar effect for large rainstorms too.<\/p>\n Catastrophic rainfall events are both immediate disasters and long term crises.\u00a0 This latter effect is all too frequently forgotten.<\/p>\n![\"\"](\"https:\/\/blogs.agu.org\/landslideblog\/files\/2017\/05\/DSCF0437-e1494486516498.jpg\")
Reference<\/h5>\n