Abstract
High-elevation and high-relief topography is the most prominent geomorphological features of the eastern margin of the Tibetan Plateau. This paper proposes that the interaction of the endogenic and exogenic forces jointly determines the formation of such high and steep landform. Eastward propagation of the Tibetan Plateau has been portioned by NW-striking, large-scaled sinistral strike-slip faults due to resistance of rigid Yangtze craton to the east of the eastern margin of the Tibetan Plateau. The transpressional stress has emerged in eastern margin of the Tibetan Plateau and has resulted in several large-scale active faults. The transpressional behavior has changed the flowing direction of the rivers from NW-SE to nearly N-S. The transport capacity of these southward-flowing rivers decreases correspondingly. Since the late Cenozoic, intensive seismic events have occurred on the active faults of the eastern Tibetan Plateau which resulted in geohazards such as slope failures, landslides along these southward-flowing rivers. This resulted in the formation of a large number of dammed lakes in the eastern margin of the Tibetan Plateau. To a certain degree, these dammed lakes play an important role in lowering the upstream erosion rate and in accelerating downstream river incision which yields gravity unloading and uplift of the bedrock. The frequently and widely distributed damming events, therefore, forms an important supplementary factor with respect to the formation of high and steep landforms.
Highlights
Rapid uplift around eastern margin of the Tibetan Plateau generated a high-elevation and high-relief topography in the formation of NE-trending mountain chains (Kirby et al, 2002), including Minshan Mountain, Longmenshan Mountain, and Gonggarshan Mountain
A comparative analysis was conducted and the results showed that the crustal-shortening strain in eastern Tibetan Plateau is much lower than that in the northeastern Tibetan Plateau, where crustal shortening can reach up to 46% (Gao et al, 2013) and varies from 20% to >60% across the southern Qilian Shan–Nan Shan thrust belt and northern Qaidam Basin (Yin et al, 2008)
Recent seismological results indicate that lower crustal flow does not universally exist, with the deformation of Eastern Tibetan Plateau being influenced by oblique thrusting of major NW-striking faults (Gao et al, 2013; Liu et al, 2015)
Summary
Rapid uplift around eastern margin of the Tibetan Plateau generated a high-elevation and high-relief topography in the formation of NE-trending mountain chains (Kirby et al, 2002), including Minshan Mountain, Longmenshan Mountain, and Gonggarshan Mountain. The shortening of the crust is not the only determinant of the formation of high and steep landforms Another model is the lower crustal flow model. Recent seismological results indicate that lower crustal flow does not universally exist, with the deformation of Eastern Tibetan Plateau being influenced by oblique thrusting of major NW-striking faults (Gao et al, 2013; Liu et al, 2015). Some studies have assumed that climate-induced surface erosion is a predominant factor that determines the formation of high and steep landforms in eastern margin of the Tibetan Plateau (England and Molnar, 1990; Molnar and England, 1990). While previous studies have provided us with possible causes, no single process offers a satisfactory interpretation to the formation and preservation of such terrain, which means the responsible dynamic mechanisms remain unclear
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