Abstract
This study examined the frequency-size distribution of 6117 landslides spread over 440 km2 in Iburi Subprefecture, Hokkaido, Japan, induced by the Hokkaido Eastern Iburi Earthquake (Mw 6.6) on September 6, 2018. The study area is characterized by gently undulating terrain that is finely dissected by shallow streams and covered predominantly by layers of volcanic products with high water content. Most of the landslides were shallow landslides, and their slip surfaces often formed in a layer of volcanic soil called the “Ta-d,” deposited at 9000 ybp. Low ridges separating small catchments allowed individual landslides to coalesce in many locations. The average size of landslides was 7160 m2. Landslide size tended to increase with slope angle up to 20° to 25° and then decrease with further increase of slope angle. About half of the landslides occurred in a feature with both concave planform and profile curvature, and their average size was 8720 m2. In contrast, 17% of the total landslides occurred in the case of both curvatures being convex, and their average size was 5190 m2. The results indicated that the accumulation of saturated soil in concave features provided more opportunities for landslides of large sizes. The frequency-size distribution of the landslides presented high rollover, 5.0 × 10−3 km2, but the exponent of power law decay for medium to large landslides, − 2.46, was not largely different from those of studies in other locations. Compared with other seismically caused examples, the landslides triggered by the Hokkaido Eastern Iburi Earthquake can be characterized as more clustered, more numerous, and larger in size for the moment magnitude of the earthquake. Conversely, the magnitude scale for the landslide event estimated from the total landslide area was equivalent to that of a region struck by an earthquake of Mw = 7.0 to 7.4. This study demonstrated that gently undulating regions can produce unexpectedly large and frequent landslides when struck by an intense earthquake, and when soil layers vulnerable to ground shaking cover the ground.
Highlights
Earthquakes can trigger numerous landslides, causing huge financial losses through damaged infrastructure and property, as well as human casualties
Determining the rollover and power law decay exponent for the region of interest is useful for hazard assessment because the frequency density, or possible number, of landslides of various sizes can be estimated by multiplying the probability by the total number of landslides, which is related to the moment magnitude of a potential earthquake (Keefer 1994)
The landslide cases that they investigated were triggered by different types of events, the equation indicated common features among them: the average size of landslides was 3.07 × 10−3 km2, rollover occurred at the size of 4.0 × 10−4 km2, and the exponent of power law decay for medium to large landslides was − 2.3
Summary
Earthquakes can trigger numerous landslides, causing huge financial losses through damaged infrastructure and property, as well as human casualties. Determining the rollover and power law decay exponent for the region of interest is useful for hazard assessment because the frequency density, or possible number, of landslides of various sizes can be estimated by multiplying the probability by the total number of landslides, which is related to the moment magnitude of a potential earthquake (Keefer 1994).
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