Analysing the impacts of extreme torrential events using multi-temporal LiDAR datasets—The Schöttlbach catchment, Upper Styria, Austria

IF 2.8 3区 地球科学 Q2 GEOGRAPHY, PHYSICAL
Paul Krenn, Nicole Kamp, Stefanie Peßenteiner, Oliver Sass
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Abstract

Extreme precipitation events in small alpine catchments trigger hazardous hydro-geomorphic processes that cause considerable damage to settlements and infrastructure. In summer 2011 and 2017, two flood events mobilizing large amounts of sediments struck the town of Oberwölz (Styria, Austria) located at the outlet of the Schöttlbach catchment. We used data from local weather stations and precipitation radar to analyse the meteorological settings that caused the flooding. We compiled a consistent sediment budget for the 2017 event by combining geomorphic mapping, connectivity analysis, high-resolution airborne LiDAR (ALS) and uncrewed aerial vehicle (UAV)-borne LiDAR (ULS), data from other authors for the 2011 event and external information (e.g., event analysis and excavation data). The 2017 event mobilized higher sediment volumes than the 2011 event (131 000 m3 vs 90 000 m3) even though 24-h precipitation and peak discharges were lower in 2017. First assumptions that the larger sediment output was caused by the reworking of the 2011 flood deposits proved to be incorrect. The impacts of the 2011 event affected the resilience of the geomorphic system resulting in a significantly higher hillslope sediment supply. We conclude that sediment transport in alpine catchments can increase disproportionately when recurrence intervals fall below a critical level.

Abstract Image

利用多时相激光雷达数据集分析极端暴雨事件的影响--奥地利上施蒂里亚州 Schöttlbach 流域
高山小流域的极端降水事件会引发危险的水文地貌过程,对居民点和基础设施造成巨大破坏。2011 年和 2017 年夏季,位于 Schöttlbach 集水区出口处的奥伯沃尔兹镇(奥地利施蒂里亚州)发生了两次洪水事件,洪水调动了大量沉积物。我们利用当地气象站和降水雷达的数据分析了造成洪水的气象环境。我们结合地貌测绘、连通性分析、高分辨率机载激光雷达(ALS)和无人飞行器机载激光雷达(ULS)、其他作者提供的 2011 年事件数据以及外部信息(如事件分析和挖掘数据),为 2017 年事件编制了一致的沉积物预算。尽管 2017 年的 24 小时降水量和峰值排水量低于 2011 年,但 2017 年事件的泥沙流量却高于 2011 年事件(131 000 立方米对 90 000 立方米)。事实证明,最初认为 2011 年洪水沉积物再加工导致沉积物输出量增加的假设是不正确的。2011 年事件的影响影响了地貌系统的恢复能力,导致山坡沉积物供应量显著增加。我们的结论是,当重现间隔低于临界水平时,高山集水区的泥沙输移会不成比例地增加。
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来源期刊
Earth Surface Processes and Landforms
Earth Surface Processes and Landforms 地学-地球科学综合
CiteScore
6.40
自引率
12.10%
发文量
215
审稿时长
4 months
期刊介绍: Earth Surface Processes and Landforms is an interdisciplinary international journal concerned with: the interactions between surface processes and landforms and landscapes; that lead to physical, chemical and biological changes; and which in turn create; current landscapes and the geological record of past landscapes. Its focus is core to both physical geographical and geological communities, and also the wider geosciences
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