Supplemental Material: Propagating uplift controls on high-elevation, low-relief landscape formation in the southeast Tibetan Plateau

High-elevation, low-relief surfaces are widespread in many mountain belts. However, the origin of these surfaces has long been debated. In particular, the southeast Tibetan Plateau has extensive low-relief surfaces perched above deep valleys and in the headwaters of three of the world’s largest rivers (Salween, Mekong, and Yangtze Rivers). Various geologic data and geodynamic models show that many mountain belts grow first to a certain height and then laterally in an outward propagation sequence. By translating this information into a kinematic propagating uplift function in a landscape evolution model, we propose that the high-elevation, low-relief surfaces in the southeast Tibetan Plateau are simply a consequence of mountain growth and do not require a special process to form. The propagating uplift forms an elongated river network geometry with broad high-elevation, low-relief headwaters and interfluves that persist for tens of millions of years, consistent with the observed geochronology. We suggest that the low-relief interfluves can be long-lived because they lack the drainage networks necessary to keep pace with the rapid incision of the large main-stem rivers. The propagating uplift also produces spatial and temporal exhumation patterns and river profile morphologies that match observations. Our modeling therefore reconciles geomorphic observations with geodynamic models of uplift of the southeast Tibetan Plateau, and it provides a simple mechanism to explain the low-relief surfaces observed in several mountain belts on Earth.

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Assessing soil erosion on a rehabilitated landform using the CAESAR landscape evolution model ©

Proceedings of the Sixth International Conference on Mine Closure ◽

10.36487/acg_rep/1152_64_lowry ◽

2011 ◽

Cited By ~ 2

Author(s):

John Lowry ◽

Tom Coulthard ◽

Gregory Hancock ◽

David Jones

Keyword(s):

Soil Erosion ◽

Landscape Evolution ◽

Evolution Model

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GRAINSIZE DEPENDENT TRANSPORT AND DEPOSITION IN A LANDSCAPE EVOLUTION MODEL

10.1130/abs/2019am-338819 ◽

2019 ◽

Author(s):

Erica Emry ◽

◽

Kyungdoe Han ◽

Michael Berry ◽

Jolante van Wijk ◽

...

Keyword(s):

Landscape Evolution ◽

Evolution Model ◽

Dependent Transport

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Linking deeply-sourced volatile emissions to plateau growth dynamics in southeastern Tibetan Plateau

Nature Communications ◽

10.1038/s41467-021-24415-y ◽

2021 ◽

Vol 12 (1) ◽

Author(s):

Maoliang Zhang ◽

Zhengfu Guo ◽

Sheng Xu ◽

Peter H. Barry ◽

Yuji Sano ◽

...

Keyword(s):

Tibetan Plateau ◽

Growth Dynamics ◽

High Elevation ◽

Fault System ◽

The Tibetan Plateau ◽

Southeastern Tibetan Plateau ◽

Surface Uplift ◽

Multi Stage ◽

Geodynamic Processes ◽

Underlying Mechanisms

AbstractThe episodic growth of high-elevation orogenic plateaux is controlled by a series of geodynamic processes. However, determining the underlying mechanisms that drive plateau growth dynamics over geological history and constraining the depths at which growth originates, remains challenging. Here we present He-CO2-N2 systematics of hydrothermal fluids that reveal the existence of a lithospheric-scale fault system in the southeastern Tibetan Plateau, whereby multi-stage plateau growth occurred in the geological past and continues to the present. He isotopes provide unambiguous evidence for the involvement of mantle-scale dynamics in lateral expansion and localized surface uplift of the Tibetan Plateau. The excellent correlation between 3He/4He values and strain rates, along the strike of Indian indentation into Asia, suggests non-uniform distribution of stresses between the plateau boundary and interior, which modulate southeastward growth of the Tibetan Plateau within the context of India-Asia convergence. Our results demonstrate that deeply-sourced volatile geochemistry can be used to constrain deep dynamic processes involved in orogenic plateau growth.

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Constructing a Landscape Evolution Model – Basic Concepts

Principles of Soilscape and Landscape Evolution ◽

10.1017/9781139029339.003 ◽

2018 ◽

pp. 11-25

Keyword(s):

Landscape Evolution ◽

Evolution Model ◽

Basic Concepts

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Tree-ring evidence of recent abnormal warming on the southeast Tibetan Plateau

Theoretical and Applied Climatology ◽

10.1007/s00704-008-0085-6 ◽

2009 ◽

Vol 98 (1-2) ◽

pp. 9-18 ◽

Cited By ~ 131

Author(s):

E. Y. Liang ◽

X. M. Shao ◽

Y. Xu

Keyword(s):

Tibetan Plateau ◽

Tree Ring ◽

Southeast Tibetan Plateau

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Diachronous Tibetan Plateau landscape evolution derived from lava field geomorphology

10.5194/egusphere-egu2020-1270 ◽

2020 ◽

Author(s):

Mark Allen ◽

Robert Law

Keyword(s):

Tibetan Plateau ◽

Landscape Evolution ◽

Tectonic Geomorphology ◽

Normal Faults ◽

The Tibetan Plateau ◽

Lava Field ◽

Northern Tibetan Plateau ◽

Tectonic Processes ◽

Stepwise Evolution

Evolution of the Tibetan Plateau is important for understanding continental tectonics because of its exceptional elevation (~5 km above sea level) and crustal thickness (~70 km). Patterns of long-term landscape evolution can constrain tectonic processes, but have been hard to quantify, in contrast to established datasets for strain, exhumation and paleo-elevation. This study analyses the relief of the bases and tops of 17 Cenozoic lava fields on the central and northern Tibetan Plateau. Analyzed fields have typical lateral dimensions of 10s of km, and so have an appropriate scale for interpreting tectonic geomorphology. Fourteen of the fields have not been deformed since eruption. One field is cut by normal faults; two others are gently folded with limb dips <6o. Relief of the bases and tops of the fields is comparable to modern, internally-drained, parts of the plateau, and distinctly lower than externally-drained regions. The lavas preserve a record of underlying low relief bedrock landscapes at the time they were erupted, which have undergone little change since. There is an overlap in each area between younger published low-temperature thermochronology ages and the oldest eruption in each area, here interpreted as the transition between the end of significant (>3 km) exhumation and plateau landscape development. This diachronous process took place between ~32.5o - ~36.5o N between ~40 and ~10 Ma, advancing northwards at a long-term rate of ~15 km/Myr. Results are consistent with incremental northwards growth of the plateau, rather than a stepwise evolution or synchronous uplift.

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Gas geochemistry of the hot spring in the Litang fault zone, Southeast Tibetan Plateau

Applied Geochemistry ◽

10.1016/j.apgeochem.2017.01.022 ◽

2017 ◽

Vol 79 ◽

pp. 17-26 ◽

Cited By ~ 12

Author(s):

Xiaocheng Zhou ◽

Lei Liu ◽

Zhi Chen ◽

Yueju Cui ◽

Jianguo Du

Keyword(s):

Tibetan Plateau ◽

Fault Zone ◽

Hot Spring ◽

Gas Geochemistry ◽

Southeast Tibetan Plateau

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Roof of the World: Tibet, Pamirs

Colliding Continents ◽

10.1093/oso/9780199653003.003.0016 ◽

2013 ◽

Author(s):

Mike Searle

Keyword(s):

Tibetan Plateau ◽

High Elevation ◽

Tien Shan ◽

Palm Tree ◽

The Tibetan Plateau ◽

Wet Season ◽

North West ◽

Mountain Ranges ◽

The North ◽

The World

The Tibetan Plateau is by far the largest region of high elevation, averaging just above 5,000 metres above sea level, and the thickest crust, between 70 and 90 kilometres thick, anywhere in the world. This huge plateau region is very flat—lying in the internally drained parts of the Chang Tang in north and central Tibet, but in parts of the externally drained eastern Tibet, three or four mountain ranges larger and higher than the Alps rise above the frozen plateau. Some of the world’s largest and longest mountain ranges border the plateau, the ‘flaming mountains’ of the Tien Shan along the north-west, the Kun Lun along the north, the Longmen Shan in the east, and of course the mighty Himalaya forming the southern border of the plateau. The great trans-Himalayan mountain ranges of the Pamir and Karakoram are geologically part of the Asian plate and western Tibet but, as we have noted before, unlike Tibet, these ranges have incredibly high relief with 7- and 8-kilometre-high mountains and deeply eroded rivers and glacial valleys. The western part of the Tibetan Plateau is the highest, driest, and wildest area of Tibet. Here there is almost no rainfall and rivers that carry run-off from the bordering mountain ranges simply evaporate into saltpans or disappear underground. Rivers draining the Kun Lun flow north into the Takla Makan Desert, forming seasonal marshlands in the wet season and a dusty desert when the rivers run dry. The discovery of fossil tropical leaves, palm tree trunks, and even bones from miniature Miocene horses suggest that the climate may have been wetter in the past, but this is also dependent on the rise of the plateau. Exactly when Tibet rose to its present elevation is a matter of great debate. Nowadays the Indian Ocean monsoon winds sweep moisture-laden air over the Indian sub-continent during the summer months (late June–September). All the moisture is dumped as the summer monsoon, the torrential rains that sweep across India from south-east to north-west.

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