Size–frequency distribution of shallow landslides in the Black Forest, Germany

Büschelberger, Matthias; Wilk, J.; Hergarten, Stefan; Preusser, Frank

doi:10.1002/esp.5237

Cited by 5 publications

(2 citation statements)

References 58 publications

(98 reference statements)

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“…Büschelberger et al ( 2022 ) analysed the size–frequency distribution of 246 historical and present‐day shallow, translational and rotational landslides in the Menzenschwand valley, Black Forest, Germany. Using a combination of LiDAR digital elevation models, near‐surface geophysics and laboratory soil tests, the study analysed the form of the size–frequency distribution.…”

Section: A Brief Overview Of Special Issue Contributionsmentioning

confidence: 99%

Special issue: German Society for Geomorphology

Heckmann

Meister

Dietze

et al. 2022

Earth Surf Processes Landf

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The German Society for Geomorphology (GSG) (Deutsche Gesellschaft für Geomorphologie: DGGM) evolved out of the German Working Group for Geomorphology in 2021, reflecting the widened scope of relevant topics and involved disciplines, the increasing importance for the professional job market and society in general, as well as the increasing importance of international cooperation and global challenges. In this special issue of the GSG we attempt to visualize the breadth in relevant methods and geomorphological subdisciplines, the wide scope of investigated temporal and spatial scales, but also the diversification in terms of career levels and gender equality. The special issue contains 25 research papers and one commentary, incorporating more than 30 German, Austrian, Swiss and other geomorphology groups, all active in the GSG, with co‐authors from virtually all continents. This editorial provides a short historical overview of the GSG's evolution, short paper summaries, a tabular paper overview and a graphical representation of contributing groups and networking, the career level and gender of all authors, relevant topics, methods, as well as temporal and spatial scales.

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Section: A Brief Overview Of Special Issue Contributionsmentioning

confidence: 99%

Special issue: German Society for Geomorphology

Heckmann

Meister

Dietze

et al. 2022

Earth Surf Processes Landf

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“…Clearly, rainfall controls on landslide spatial distribution differ depending on rainfall characteristics and local terrain settings (e.g., Bogaard and Greco, 2018). Even during the same triggering rainfall event, multiple inventories showed discrepancies in landslide occurrence timing and geometric features (e.g., area, volume, and depth) at the catchment (Yamada et al, 2012;Yano et al, 2019;Guzzetti et al, 2004) and hillslope scales (Büschelberger et al, 2022). This suggests that landslides are triggered by disparate rainfall timespans due to different hydromechanical responses of hillslopes to forcing rainfall.…”

Section: Introductionmentioning

confidence: 99%

Revealing the relation between spatial patterns of rainfall return levels and landslide density

Mtibaa

Tsunetaka

2023

Earth Surf. Dynam.

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Abstract. It is known that the spatial rainfall pattern can mark landslide distribution across the landscape during extreme triggering events. However, the current knowledge of rainfall controls on this distribution remains limited. Here, to reveal what rainfall characteristics control landslide spatial distribution, we explore the spatiotemporal pattern of a rainfall event that triggered over 7500 landslides (area ≈ 100–104 m2) at a regional scale with an area of ≈400 km2 in Japan. Using a 5 km resolution radar-driven and gauge-adjusted hourly precipitation dataset with 32 years of records, we compared rainfall return levels for various time ranges from 1 to 72 h and landslide density in each grid cell of the precipitation dataset (≈25 km2). The results show that, even if local slope distributions within the grid cells are comparable, the number of landslides in a ≈25 km2 grid cell was substantially high when rainfall return levels exceeded the 100-year return period in all examined timespans (i.e., 1–72 h). In contrast, when only specific-duration rainfall intensities (e.g., 6–48 h) exceeded the 100-year return level, the landslide density in corresponding grid cells tended to be low. Consequently, the landslide density increased with the increase in rainfall return levels of various timespans rather than a specific rainfall intensity, such as downpours for a few hours or long-term cumulative rainfall for several days. Moreover, with the increase in the landslide density, the number of relatively large landslides exceeding ≈400 m2 increased. Therefore, the spatial differences in rainfall return levels potentially constrain the density of total landsliding and relatively large landslides. In this sense, whether rainfall intensities reach high return levels rarely experienced in a wide timespan ranging from a few hours to several days is one of the key determinants of the spatial distribution of landslides and the extent of related hazards.

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Evaluation of the impact of climate change on rainfall for potential landslide triggering in Japan

Tsunetaka,

Murakami,

Nakao

et al. 2024

Earth Surf Processes Landf

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Intense rainfall events associated with climate change may increase future landslide hazards. Therefore, future landslide probability should be constrained using rainfall projections from global climate models (GCMs). However, because landslides can occur in association with various rainfall patterns, such as short‐duration (few hours) intense rainfall to long‐term accumulated rainfall over a few days, general projections of daily rainfall are inadequate for evaluation of rainfall with landslide‐triggering potential. To address this problem, this study adopted a new approach using 72‐h GCM rainfall projections based on 100‐year rainfall return levels and applied it to 10 regions in Japan where landslides widely occur. We found that rainfall with landslide‐triggering potential becomes more frequent toward 2,100 in response to intensified global warming. In some regions, under the scenario that future greenhouse gas emissions continue to increase owing to inadequate regulation, intense rainfall with landslide‐triggering potential is projected to become more frequent and widespread, especially after approximately 2060. In relation to this projected spread of the areas of persistent rain, rainfall with landslide‐triggering potential might occur synchronously in two to five regions. However, even under the scenario that aerosol emissions are reduced rapidly to mitigate global warming, rainfall might intensify before 2060 in some regions, resulting in a projection of high landslide probability. The presented projections are not definitive and require further refinement; however, they do suggest that the impact of climate change on the frequency and region of hazard of landslide occurrence might change in the future depending on the effort made to mitigate global warming.

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Size–frequency distribution of shallow landslides in the Black Forest, Germany

Cited by 5 publications

References 58 publications

Special issue: German Society for Geomorphology

Special issue: German Society for Geomorphology

Revealing the relation between spatial patterns of rainfall return levels and landslide density

Evaluation of the impact of climate change on rainfall for potential landslide triggering in Japan

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