Convective forcing of the North American Monsoon anticyclone at intraseasonal and interannual time scales

In the upper troposphere and lower stratosphere (UTLS), large-scale anticyclones associated with monsoons play major roles in tropospheric and stratospheric transport and mixing. To understand the forcing of the North American monsoon anticyclone (NAMA), this study examines the connection between pr...

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Bibliographic Details
Published in:Journal of the atmospheric sciences 2021-09, Vol.78 (9), p.2941-2956
Main Authors: Chang, Kai-Wei, Bowman, Kenneth P, Siu, Leong Wai, Rapp, Anita D
Format: Article
Language:English
Subjects:
Anomalies
Anticyclones
Anticyclonic circulation
Circulation anomalies
Correlation
Diabatic heating
Dynamic height
General circulation models
Geopotential
Geopotential height
Heating
Long wave radiation
Lower stratosphere
Monsoons
North American monsoon
Planetary waves
Precipitation
Radiation
Rossby waves
Stratosphere
Temperature
Temperature anomalies
Time
Tropical environments
Troposphere
Upper troposphere
Vertical profiles
Wind
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Summary:In the upper troposphere and lower stratosphere (UTLS), large-scale anticyclones associated with monsoons play major roles in tropospheric and stratospheric transport and mixing. To understand the forcing of the North American monsoon anticyclone (NAMA), this study examines the connection between precipitation over the tropics and subtropics of the North American longitude sector and the variability of the troposphere and lower stratosphere. Using ERA5 reanalysis and outgoing longwave radiation (OLR) data from 1979âĂŞ2019, we assess the relationship at the intraseasonal time scale using pentad-mean time series. We show that OLR anomalies are correlated with circulation anomalies northwest and northeast of the region of precipitation. Decreased OLR (increased precipitation) corresponds to increased geopotential heights and anticyclonic circulation anomalies in the 300 - 100 hPa layer and an opposite response in the lower tropospheric 850 - 600 hPa layer. The results are consistent with the established theory of the Rossby wave response to latent heating. The increase in height, which is strongest near 150 hPa, indicates that increased precipitation is associated with a strengthened NAMA. UTLS temperatures also have significant correlations with OLR, with cold (warm) anomalies occurring above (below) the core of the anticyclonic anomaly consistent with large-scale balance. The vertical structure of geopotential and temperature anomalies is compared to simulations using an idealized general circulation model, which shows that such a vertical structure is a consistent response to diabatic heating. Correlations at the interannual time scale resemble those at the intraseasonal time scale, demonstrating that precipitation is related to the NAMA at both time scales.
ISSN:0022-4928
1520-0469
DOI:10.1175/jas-d-21-0009.1