Editorial Type:
Article
Article Type:
Research Article

Dynamics and Thermodynamics of the Regional Response to the Indian Monsoon Onset

Roop Saini Department of Environmental, Earth and Atmospheric Sciences, University of Massachusetts Lowell, and University of Massachusetts School of Marine Sciences, Lowell, Massachusetts

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Mathew Barlow Department of Environmental, Earth and Atmospheric Sciences, University of Massachusetts Lowell, and University of Massachusetts School of Marine Sciences, Lowell, Massachusetts

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Andrew Hoell Department of Environmental, Earth and Atmospheric Sciences, University of Massachusetts Lowell, and University of Massachusetts School of Marine Sciences, Lowell, Massachusetts

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Print Publication:
15 Nov 2011
DOI:
https://doi.org/10.1175/2011JCLI3928.1
Page(s):
5879–5886
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Abstract

The regional influence of the Indian monsoon onset is examined though observational analysis focusing on the Rodwell–Hoskins “monsoon-desert” hypothesis, which proposes that the strong diabatic heating associated with the monsoon produces a Gill-like Rossby wave response that thermodynamically interacts with the midlatitude westerly jet to produce subsidence and reduced rainfall to the west of the monsoon. Here, the authors analyze this proposed mechanism in terms of changes to the thermodynamic energy equation, regional circulation, and precipitation between the 10-day periods before and after the monsoon onset, for all onset dates in the 1958–2000 period. A Rossby-like response to the monsoon onset is clear in the observational data and is associated with horizontal temperature advection at midlevels as the westerlies intersect the warm temperature anomalies of the Rossby wave. Analysis of the thermodynamic equation verifies that the horizontal temperature advection is indeed balanced by subsidence over areas of North Africa, the Mediterranean, and the Middle East, and there is an associated decrease in precipitation over those regions. Despite the increased subsidence, diabatic heating changes are small in these regions so diabatic enhancement does not appear to be a primary factor in the response to the onset. This analysis also shows that the same processes that favor subsidence to the west of the monsoon also force rising motion over northern India and appear to be an important factor for the inland development of the monsoon. Comparison of strong and weak onsets further validates these relationships.

Corresponding author address: R. Saini, 1 University Avenue, University of Massachusetts Lowell, Lowell, MA 01854. E-mail: roop_saini@student.uml.edu

Abstract

The regional influence of the Indian monsoon onset is examined though observational analysis focusing on the Rodwell–Hoskins “monsoon-desert” hypothesis, which proposes that the strong diabatic heating associated with the monsoon produces a Gill-like Rossby wave response that thermodynamically interacts with the midlatitude westerly jet to produce subsidence and reduced rainfall to the west of the monsoon. Here, the authors analyze this proposed mechanism in terms of changes to the thermodynamic energy equation, regional circulation, and precipitation between the 10-day periods before and after the monsoon onset, for all onset dates in the 1958–2000 period. A Rossby-like response to the monsoon onset is clear in the observational data and is associated with horizontal temperature advection at midlevels as the westerlies intersect the warm temperature anomalies of the Rossby wave. Analysis of the thermodynamic equation verifies that the horizontal temperature advection is indeed balanced by subsidence over areas of North Africa, the Mediterranean, and the Middle East, and there is an associated decrease in precipitation over those regions. Despite the increased subsidence, diabatic heating changes are small in these regions so diabatic enhancement does not appear to be a primary factor in the response to the onset. This analysis also shows that the same processes that favor subsidence to the west of the monsoon also force rising motion over northern India and appear to be an important factor for the inland development of the monsoon. Comparison of strong and weak onsets further validates these relationships.

Corresponding author address: R. Saini, 1 University Avenue, University of Massachusetts Lowell, Lowell, MA 01854. E-mail: roop_saini@student.uml.edu
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