direkt zum Inhalt springen

direkt zum Hauptnavigationsmenü

Sie sind hier

TU Berlin

Page Content



Experimental investigation of freeze-thaw meltwater compound erosion and runoff energy consumption on loessal slopes
Citation key WANG2020104310
Author Tian Wang and Peng Li and Ying Liu and Jingming Hou and Zhanbin Li and Zongping Ren and Shengdong Cheng and Jiaheng Zhao and Reinhard Hinkelmann
Pages 104310
Year 2020
ISSN 0341-8162
DOI https://doi.org/10.1016/j.catena.2019.104310
Journal CATENA
Volume 185
Abstract The processes of rill erosion and overland flow are significantly affected by freeze-thaw cycles. Meltwater concentrated flow laboratory experiments were carried out to assess the soil erosion of different frozen conditions based on the runoff energy consumption process which own to runoff energy against the sediment transportation and terrain evolution. The experiments were performed over frozen, shallow-thawed, and unfrozen soil-filled flumes under 1, 2, and 4 L/min flow rates with the temperature around 5 °C. The results imply that soil erosion became more severe with increasing flow rate. Variation rate of the soil erosion rate of frozen slope was highest under 1 and 2 L/min flow rates due to lower infiltration of water into soil. Variation in runoff energy consumption variation with flow time presented significant differences under unfrozen, shallow-thawed, and frozen slopes at equal runoff rate (p < 0.05). Compared with shallow-thawed and unfrozen slopes, frozen slope displayed the highest runoff energy consumption and sediment yield capacity at the equal flow rate. Sediment yield capacity was constant regardless of soil condition except in shallow-thawed soil. The sediment yield capacity under 4 L/min flow rate was different from that under 1 and 2 L/min flow rates for shallow-thawed slopes. Soil erosion rates were predictable using runoff energy consumption under one soil condition. The results of this research would provide specific implications about meltwater erosion process and hydrodynamic conditions for improving the erosion model.
Link to publication Download Bibtex entry

Zusatzinformationen / Extras

Quick Access:

Schnellnavigation zur Seite über Nummerneingabe

Auxiliary Functions