Assessing the role of thermal erosion in channel deformation processes in rivers of permafrost zone

The study is focused on the deformations caused by the impact of water flow in a river channel composed of melt-able permafrost rocks. It is based on the results of laboratory and mathematical simulation. The results of numerical calculations are compared with data of laboratory and field observatio...

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Bibliographic Details
Published in:E3S Web of Conferences
Main Authors: Debolskaya E., Maslikova O., Gritsuk I.
Format: Article in Journal/Newspaper
Language:English
Published: EDP Sciences
Subjects:
Ablation
Flow of water
Heat transfer
Hydrology
Permafrost
Rivers
Sediment transport
Sedimentation
Adequate models
Comprehensive model
Deformation process
Field observations
Mathematical simulations
Non-simultaneous
Numerical calculation
Numerical experiments
Deformation
permafrost
Online Access:https://repository.rudn.ru/records/article/record/64836/
Description
Summary:The study is focused on the deformations caused by the impact of water flow in a river channel composed of melt-able permafrost rocks. It is based on the results of laboratory and mathematical simulation. The results of numerical calculations are compared with data of laboratory and field observations. The study shows that a comprehensive and adequate model of river channel deformations should take into account not only ablation, but also other factors, including heat transfer in the soil, sediment transport, and bank slope collapses. Numerical experiments with an improved mathematical model, applied to long time intervals, have shown that the differences between the averaged deformations, calculated by a model of ablation alone, i.e., ignoring bank slope collapses and sediment transport, and a comprehensive model can be considerable. Experiments in a hydraulic flume were good enough to reproduce the effect of delayed collapse, consisting in nonsimultaneous impacts of channel-forming rock melting and a freshet. © 2020 The Authors, published by EDP Sciences.

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