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Exhumation and uplift of the Shillong plateau and its influence on the eastern Himalayas: New constraints from apatite and zircon (U‐Th‐[Sm])/He and apatite fission track analyses
Author(s) -
Biswas Subrata,
Coutand Isabelle,
Grujic Djordje,
Hager Christian,
Stöckli Daniel,
Grasemann Bernhard
Publication year - 2007
Publication title -
tectonics
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.465
H-Index - 134
eISSN - 1944-9194
pISSN - 0278-7407
DOI - 10.1029/2007tc002125
Subject(s) - geology , plateau (mathematics) , fission track dating , zircon , thermochronology , tectonics , foreland basin , basement , tectonic uplift , geomorphology , paleontology , geochemistry , mathematical analysis , civil engineering , mathematics , engineering
The Shillong plateau is the only raised topography in the foreland of the Himalayas. Located on the trajectory of the Indian Summer Monsoon (ISM), the plateau perturbs the regional distribution of precipitation. As such, the Shillong plateau‐eastern Himalaya‐ISM is a unique system to quantify the couplings between climate, tectonics, and erosion. A change in long‐term erosion rates along‐strike of the Bhutan Himalaya was recently attributed to a climatic modulation due to the uplift of the Shillong plateau. To test this interpretation, it is essential to constrain the timing and rate at which the plateau was uplifted and the amount of partitioning of the India‐Asia convergence into the plateau. We used apatite and zircon (U‐Th‐[Sm])/He and apatite fission track analyses to unravel the thermal histories of 13 basement samples collected along a N‐S transect across the central Shillong plateau. We find that (1) the exhumation of the plateau began at least 9–15 Ma ago, (2) its surface uplift was chronologically decoupled from its exhumation and started after ∼3–4 Ma at rates of 0.4–0.53 mm/a, (3) the long‐term horizontal shortening rate accommodated by the plateau is 0.65–2.3 mm/a, which represents only 10–15% of the India‐Asia convergence rate. The uplift of the Shillong plateau did not significantly modify the rock uplift rate in the Bhutan Himalaya, which is consistent with the hypothesis of climatic modulation of the Pliocene erosion, tectonic, and landscape evolution previously documented along this orogenic front.