Miocene to Pleistocene floras and climate of the Eastern Himalayan Siwaliks, and new palaeoelevation estimates for the Namling–Oiyug Basin, Tibet

Miocene to Pleistocene floras and climate of the Eastern Himalayan Siwaliks, and new palaeoelevation estimates for the Namling–Oiyug Basin, Tibet

Four fossil floras ranging in age from the mid Miocene to the early Pleistocene from the eastern Siwaliks near Darjeeling and in Arunachal Pradesh (AP) were compared taxonomically and subjected to a CLAMP (Climate Leaf Analysis Multivariate Program) analysis using a new calibration dataset that incl...

Full description

Saved in:
Bibliographic Details
Published in:Global and planetary change Vol. 113; pp. 1 - 10
Main Authors: Khan, Mahasin Ali, Spicer, Robert A., Bera, Subir, Ghosh, Ruby, Yang, Jian, Spicer, Teresa E.V., Guo, Shuang-xing, Su, Tao, Jacques, Frédéric, Grote, Paul J.
Format: Journal Article
Language:English
Published: Amsterdam Elsevier B.V 01-02-2014
Elsevier
Subjects:
Basins
Climate change
Earth sciences
Earth, ocean, space
Elevation
Enthalpy
Estimates
Exact sciences and technology
India
Monsoon
Monsoons
Neogene
Palaeoelevation
Paleobotany
Paleontology
Sea level
Stratigraphy
Tibet
Uncertainty
Xizang China
Southern China
Asia
China
Himalayas
Siwalik Range
Far East
Thailand
India
Pakistan, Himalayas
China, People's Rep., Xizang
ISEW, Thailand
India, Arunachal Pradesh
China, People's Rep
Neogene
Climate change
Monsoon
Tibet
Palaeoelevation
India
altitude
flora
upper Tertiary
vegetation
taxonomy
enthalpy
paleoclimate
leaves
tectonics
Cenozoic
uncertainties
climate change
rainfall
paleorelief
atmospheric precipitation
Quaternary
paleotemperature
Tertiary
Plantae
Pliocene
Miocene
Phanerozoic
monsoons
Pleistocene
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Four fossil floras ranging in age from the mid Miocene to the early Pleistocene from the eastern Siwaliks near Darjeeling and in Arunachal Pradesh (AP) were compared taxonomically and subjected to a CLAMP (Climate Leaf Analysis Multivariate Program) analysis using a new calibration dataset that includes sites from India, southern China and Thailand and high resolution gridded climate data. Two lower Siwalik mid Miocene floras yielded almost the same values suggesting mean annual temperatures (MATs) of 25.4 and 25.3°C±2.8°C (all uncertainties ±2 sigma) with warm month mean temperatures (WMMTs) of 28.4 and 27.8±3.39°C and cold month mean temperatures (CMMTs) of 17.9 and 21.3±4°C. Precipitation estimates have high uncertainties but suggest a weak monsoon with growing season precipitations of 242±92cm for Darjeeling and 174±92cm for AP. Leaves from the middle Siwalik (Pliocene) sediments of AP indicate a lowering of the MAT to 23.7°C, a function of cooler winter months (CMMT 16.9°C). The AP early Pleistocene temperatures and rainfall were similar to those of the mid Miocene. Changes in the monsoon index suggest that in the AP area there has been little change in the intensity of the monsoon since mid Miocene time, while further west at Darjeeling there has been an intensification since the mid Miocene. Mid Miocene CLAMP-derived enthalpy estimates provide sea level (<200a.m.s.l.) data for a re-evaluation of the palaeoelevation of a 15Ma flora from the Namling–Oiyug Basin, southern Tibet. Enthalpy values from Darjeeling and AP were 354.1 and 355.8±10.3kJ/kg respectively, while that derived from the Namling–Oiyug flora was 296.3kJ/kg. This yields a palaeoelevation of 5888m for the Namling site using the Darjeeling enthalpy estimate as a sea level datum and 6065m using the AP assemblage. The combined uncertainty is ±728m. Model corrected enthalpy trends at sea level across palaeolatitude and longitude reduce the mean elevation to 5.54km. These elevations are higher than earlier estimates from the same site (but within uncertainty) and the corrected mean is ~1km higher than the present day basin floor elevation in the region, suggesting some deflation since 15Ma associated with east–west extension, particularly if a shift in the locus of deformation and uplift south to the Himalayas in post middle Miocene times relieved N–S compressional stress on southern Tibet. •Tropical Neogene forests of NE India experienced a weaker monsoon than now.•By contrast 15Ma Tibetan leaf fossils indicate a cool climate, wetter than now.•Analysis of leaf fossil architecture shows S. Tibet was 1km higher than now at 15Ma.•Height loss since 15Ma could be due to erosion or, more likely, lower crustal flow.•Monsoon strengthening and a lower Tibet suggest uplift has shifted to the Himalayas.
Bibliography:ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:0921-8181
1872-6364
DOI:10.1016/j.gloplacha.2013.12.003