Theoretical aspects of the onset of Indian summer monsoon from perturbed orography simulations in a GCM

Chakraborty, Arun; Nanjundiah, Ravi S.; Srinivasan, J.

doi:10.5194/angeo-24-2075-2006

Cited by 71 publications

(80 citation statements)

References 32 publications

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“…Observations corroborate such theory [Bordoni and Schneider, 2008;Hurley and Boos, 2013;Nie et al, 2010]. Chakraborty et al [2006], in particular, suggested that the moist static energy just above the surface of India could be used to predict the date of onset of the Indian monsoon.…”

Section: Introductionsupporting

confidence: 61%

“…For MSE, we explored different windows ( Figure S1 in the supporting information) and chose periods that precede the early and late seasons used here by enough that predictions should be possible. The correlation of MSE in the period 1 May to 15 May with All India Rainfall in the period 20 May to 15 June (Figure 1a) shows a large region of positive correlation covering central and north India (including Tibet) and Pakistan, as Chakraborty et al [2006] anticipated. This correlation indicates that heating over this region during the preceding period favors high rainfall during the early season.…”

Section: Predictor Selectionmentioning

confidence: 71%

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Combining regional moist static energy and ENSO for forecasting of early and late season Indian monsoon rainfall and its extremes

Rajagopalan

Molnár

2014

Geophysical Research Letters

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We exploit El Niño-Southern Oscillation (ENSO) indices and moist static energy of surface air over the Indian subcontinent and surroundings as predictors of monsoon rainfall over India during early and late seasons, defined here as 20 May to 15 June and 20 September to 15 October, respectively. Although these seasons contribute only~22% of the entire seasonal rainfall, they clearly affect planning of agriculture and water resources. A simple, nonlinear, statistical model applied to these predictors accounts for~40% and 45% of the observed variance of early and late season rainfall, respectively, and similar fractions for 3 day maximum rainfall intensity. Forecasted average and 3 day maximum rainfall at grid points covering India show greatest success over central India during the early season and over west central, northwestern, and northern India during the late season, regions where agriculture dominates land use. These predictors, however, offer virtually no predictability of peak season rainfall.

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Section: Introductionsupporting

confidence: 61%

Section: Predictor Selectionmentioning

confidence: 71%

Combining regional moist static energy and ENSO for forecasting of early and late season Indian monsoon rainfall and its extremes

Rajagopalan

Molnár

2014

Geophysical Research Letters

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“…For the late season, correlation coefficients are yet higher, and the band of high correlation extends southwest from Tibet. These correlations suggest a direct relationship between heating of the atmosphere directly above Tibet's surface, and the temperature in the upper troposphere, which many link both to the strength of the monsoon [e.g., Goswami et al, 1999;He et al, 1987He et al, , 2003Li and Yanai, 1996;Wu and Zhang, 1998;Yanai and Wu, 2006;Yanai et al, 1992] and, as Chakraborty et al [2006] suggested, to its onset [e.g., Goswami and Xavier, 2005;Xavier et al, 2007;Webster and Yang, 1992].…”

Section: Resultsmentioning

confidence: 99%

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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“…Some studies pointed out that the presence of the African plateau was relevant to the Asian monsoon. In numerical experiments by Chakraborty et al [81] the removal of the African topography could delay the onset of the South Asian summer monsoon and weaken its intensity, while once the South Asian summer monsoon was established, the influence of topography on the precipitation intensity was limited. Earlier experiments by Chakraborty et al [75] demonstrated the importance of the African topography in the formation of the Indian monsoon, but the result was that the removal of the African topography led to increased precipitation in the Indian Subcontinent.…”

Section: Contributions Of Other Tectonic Movements To the Establishmementioning

confidence: 99%

“…Not only did the uplifts of southern and northern TP have different climatic and environmental influences, but the effects of the eastern and western topography as well. The numerical experiments of Chakraborty et al [81] discovered that the Asian topography to the west of 80°E had a greater impact than that to the east of 80°E on the onset of the Indian summer monsoon and associated precipitation. The western plateau had a barrier effect on the cold air from high latitudes, favored the atmosphere over south Asia to reach unstable conditions earlier; while the eastern plateau played a minor role in promoting the development of deep convection over the entire Indian region, despite enhancing large-scale ascending air flow in the lower troposphere.…”

Section: Effects Of Himalayan-tibetan Plateau Sub-regional Uplift On mentioning

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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Theoretical aspects of the onset of Indian summer monsoon from perturbed orography simulations in a GCM

Cited by 71 publications

References 32 publications

Combining regional moist static energy and ENSO for forecasting of early and late season Indian monsoon rainfall and its extremes

Combining regional moist static energy and ENSO for forecasting of early and late season Indian monsoon rainfall and its extremes

Signatures of Tibetan Plateau heating on Indian summer monsoon rainfall variability

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

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