Topographic disequilibrium, landscape dynamics and active tectonics: an example from the Bhutan Himalayas
- 1Université de Paris, Institut de physique du globe de Paris, CNRS, F-75005 Paris, France (simoes@ipgp.fr)
- 2Géosciences Montpellier, Université de Montpellier, CNRS, Université des Antilles, Montpellier, France
- 3Géolithe, 38920, Crolles, France
- 4Department of Geology and Mines, Thimphu, Bhutan
The quantification of active tectonics from geomorphological and morphometric approaches most often implies that erosion and tectonics have reached a certain balance. Such equilibrium conditions may however be seldom found in nature, in particular because drainage basins may be quite dynamic even though tectonic and climatic conditions remain constant. Here, we document this drainage dynamics from the particular case example of the Bhutan Himalayas. Evidence for out-of-equilibrium morphologies have for long been noticed in Bhutan, from major (> 1 km high) river knickpoints and from the existence of high-altitude low-relief regions within the mountain hinterland. These peculiar morphologies were generally interpreted as representing a recent change in climatic and/or tectonic conditions. To further characterize these morphologies and their dynamics, and from there discuss their origin and meaning, we perform field observations and a detailed quantitative morphometric analysis using Chi plots and Gilbert metrics of drainages over various spatial scales, from major Himalayan rivers to local streams draining the low-relief regions. We first find that the river network is highly dynamic and unstable. Our results emphasize that the morphology of Bhutan does not result from a general wave of incision propagating upstream, as expected from most previous interpretations. Also, the specific spatial organization in which all major knickpoints and low-relief regions are located along a longitudinal band in the Bhutan hinterland, whatever their spatial scale and the dimensions of the associated drainage basins, calls for a common local supporting mechanism most probably related to active tectonic uplift. Our results emphasize the need for a precise documentation of landscape dynamics and disequilibrium over various spatial scales as a first-order step in morpho-tectonic studies of active landscapes.
How to cite: Simoes, M., Sassolas-Serrayet, T., Cattin, R., Le Roux-Mallouf, R., Ferry, M., and Drukpa, D.: Topographic disequilibrium, landscape dynamics and active tectonics: an example from the Bhutan Himalayas, EGU General Assembly 2021, online, 19–30 Apr 2021, EGU21-1322, https://doi.org/10.5194/egusphere-egu21-1322, 2021.
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