Constant elevation of southern Tibet over the past 15 million years

Spicer, Robert A.; Harris, Nigel; Widdowson, Mike; Herman, Alexei B.; Guo, Shaojun; Valdes, Paul J.; Wolfe, Jack A.; Kelley, Simon P.

doi:10.1038/nature01356

Cited by 575 publications

(438 citation statements)

References 21 publications

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“…One explanation for these changes is that at that time the surface of the plateau rose abruptly 1000 m or more [e.g., Harrison et al, 1992;Molnar et al, 1993], but much less than the full 5000 m present-day elevation of the plateau. Estimates of paleo-elevations of southern Tibet do not support, but rather contradict, this idea; essentially all such estimates show little change since 10 Ma to perhaps 25-35 Ma [Currie et al, 2005;DeCelles et al, 2007;Garzione et al, 2000aGarzione et al, , 2000bRowley and Currie, 2006;Rowley et al, 2001;Saylor et al, 2009;Spicer et al, 2003]. Because uncertainties in all arẽ 1000 m, however, let us consider the possibility that the average elevation of Tibet was 1000 m lower at 10-15 Ma than today.…”

Section: Discussion: Possible Relevance To Paleoclimatementioning

confidence: 85%

Signatures of Tibetan Plateau heating on Indian summer monsoon rainfall variability

Rajagopalan

Molnár

2013

JGR Atmospheres

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[1] Despite recent challenges, conventional wisdom has held that heating over the Tibetan Plateau leads to increased Indian summer monsoon rainfall via enhancement of cross-equatorial circulation aloft, and a concurrent strengthening of both the Somali Jet and westerly winds that bring moisture to southern India. We show that such heating, quantified by monthly estimates of moist static energy in the atmosphere just above the surface, correlates with summer monsoon rainfall, but only in the early (20 May to 15 June) and late (September 1 to 15 October) monsoon season. Correlations during the main monsoon season (15 June to 31 August) are small and insignificant. The positive correlations with early and late monsoon season, however, allow for heating over Tibet to modulate as much as 30% of the total rainfall. Furthermore, we demonstrate that heating over Tibet is independent of the El Niño Southern Oscillation, so that together they explain a substantial portion of variability in the early and late season rainfall, providing potential predictability. These links may also explain the wet conditions over India during early Holocene time and provide a quantitative link between a rise of Tibet and stronger Somali Jet.

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Section: Discussion: Possible Relevance To Paleoclimatementioning

confidence: 85%

Signatures of Tibetan Plateau heating on Indian summer monsoon rainfall variability

Rajagopalan

Molnár

2013

JGR Atmospheres

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“…Uplift of the plateau began approximately 40 million years ago (Mya) in the Eocene (Chung et al, 1998). Recent evidence indicates that the southern margin reached its present elevation approximately 15-22 Mya (Guo et al, 2002;Spicer et al, 2003) and that the whole plateau may have attained its present altitude by 7-8 Mya (Harrison et al, 1992). Orogeny along the eastern margin of the plateau since the early Miocene ($22 Mya) has created high mountains and deep valleys (Li et al, 1995), which are thought to have profoundly accelerated the diversification of plant species through local vicariance, secondary contact, and ecological speciation events (Liu et al, 2006).…”

Section: Introductionmentioning

confidence: 99%

Evolutionary events in Lilium (including Nomocharis, Liliaceae) are temporally correlated with orogenies of the Q–T plateau and the Hengduan Mountains

Gao

Harris

Zhou

et al. 2013

Molecular Phylogenetics and Evolution

136

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“…For instance, the Yangbajing graben northwest of Lhasa [19], vegetation succession from forest to grassland in northern Pakistan [20] and enhanced upwelling current on the Arabian Sea coast [21] were all recognized as important evidence for the TP uplift during the late Miocene, and some scholars believed that the TP could have reached its full height around 8 Ma [19]. Afterwards some researchers speculated that the TP had basically reached its maximum height in the middle Miocene (14-15 Ma), and then changed little or even declined slightly according to research on the timing of Himalayan normal fault activity [22] and fossil leaves of paleoplants in southern Tibet [23]. Recently some scholars, based upon magnetic stratigraphy and sedimentology studies of basins in the central and northern TP [24] and the oxygen isotope data of basins in the central TP [25], recognized that the central TP could have reached its current height in the middle and late Eocene .…”

Section: Geological Recordsmentioning

confidence: 99%

“…Meanwhile, the eolian deposition also recorded the long-term process of aridification in inland Asia. The oldest eolian loess found in northern China appeared in the early Miocene (22)(23)(24)(25) [4,33,34], a critical period around which the environment transformed from a planetary circulation system into a monsoon-dominated pattern, as indicated by integrated studies of Asian paleoenvironmental records [35][36][37]. Both continental [38] and marine [39] eolian deposition records showed that aridification of inland Asia was significantly intensified during recent 3-4 Ma since the Pliocene.…”

Section: Geological Recordsmentioning

confidence: 99%

Influence of the Tibetan Plateau uplift on the Asian monsoon-arid environment evolution

2013

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As one of the most important geological events in Cenozoic era, the uplift of the Tibetan Plateau (TP) has had profound influences on the Asian and global climate and environment evolution. During the past four decades, many scholars from China and abroad have studied climatic and environmental effects of the TP uplift by using a variety of geological records and paleoclimate numerical simulations. The existing research results enrich our understanding of the mechanisms of Asian monsoon changes and interior aridification, but so far there are still a lot of issues that need to be thought deeply and investigated further. This paper attempts to review the research on the influence of the TP uplift on the Asian monsoon-arid environment, summarize three types of numerical simulations including bulk-plateau uplift, phased uplift and sub-regional uplift, and especially to analyze regional differences in responses of climate and environment to different forms of tectonic uplifts. From previous modeling results, the land-sea distribution and the Himalayan uplift may have a large effect in the establishment and development of the South Asian monsoon. However, the formation and evolution of the monsoon in northern East Asia, the intensified dryness north of the TP and enhanced Asian dust cycle may be more closely related to the uplift of the main body, especially the northern part of the TP. In this review, we also discuss relative roles of the TP uplift and other impact factors, origins of the South Asian monsoon and East Asian monsoon, feedback effects and nonlinear responses of climatic and environmental changes to the plateau uplift. Finally, we make comparisons between numerical simulations and geological records, discuss their uncertainties, and highlight some problems worthy of further studying.Tibetan Plateau, tectonic uplift, Asian monsoon, inland aridity, environmental evolution, geological record, numerical simulation Citation:Liu X D, Dong B W.

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Constant elevation of southern Tibet over the past 15 million years

Cited by 575 publications

References 21 publications

Signatures of Tibetan Plateau heating on Indian summer monsoon rainfall variability

Signatures of Tibetan Plateau heating on Indian summer monsoon rainfall variability

Evolutionary events in Lilium (including Nomocharis, Liliaceae) are temporally correlated with orogenies of the Q–T plateau and the Hengduan Mountains

Influence of the Tibetan Plateau uplift on the Asian monsoon-arid environment evolution

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