Abstract
The often-used phrase ‘the uplift of the Tibetan Plateau’ implies a flat-surfaced Tibet rose as a coherent entity, and that uplift was driven entirely by the collision and northward movement of India. Here, we argue that these are misconceptions derived in large part from simplistic geodynamic and climate modeling, as well as proxy misinterpretation. The growth of Tibet was a complex process involving mostly Mesozoic collisions of several Gondwanan terranes with Asia, thickening the crust and generating complex relief before the arrival of India. In this review, Earth system modeling, paleoaltimetry proxies and fossil finds contribute to a new synthetic view of the topographic evolution of Tibet. A notable feature overlooked in previous models of plateau formation was the persistence through much of the Cenozoic of a wide east–west orientated deep central valley, and the formation of a plateau occurred only in the late Neogene through compression and internal sedimentation.
Highlights
Over an area of 2500 000 km2, the modern Qinghai–Tibetan Plateau (Fig. 1) is the most extensive elevated surface on Earth
Earth system modeling, paleoaltimetry proxies and fossil finds contribute to a new synthetic view of the topographic evolution of Tibet
The presence of the plateau is thought to exert profound influences on the Asian monsoon systems, and by extension Asian biodiversity, so understanding the evolution of Tibetan topography is critical for exploring the links between them
Summary
Over an area of 2500 000 km, the modern Qinghai–Tibetan Plateau (Fig. 1) is the most extensive elevated surface on Earth. The recent discovery in the northern Qaidam Basin of a cool temperate predominantly deciduous early Oligocene flora challenges that view [85], as does hydrogen isotope data from the Hoh Xil Basin [86], like other inland stable isotope paleoaltimetry this needs to be re-evaluated using isotope-enabled climate model mediation to better quantify the source of isotopic composition and the air parcel trajectory/continental effect [61] This implies an Eocene uplift of the region or a pre-existing uplift derived from pre-Cenozoic terrane collisions. The influence of the Himalaya on atmospheric circulation (deflection of air parcel trajectories and a rain shadow effect over Tibet) only really began to operate from the middle Miocene onward [120]
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