A Dynamical Perspective on Atmospheric Temperature Variability and Its Response to Climate Change

The atmospheric temperature distribution is typically described by its mean and variance, while higher-order moments, such as skewness, have received less attention. Skewness is a measure of the asymmetry between the positive and negative tails of the distribution, which has implications for extreme...

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Bibliographic Details
Published inJournal of climate Vol. 32; no. 6; pp. 1707 - 1724
Main Authors Tamarin-Brodsky, Talia, Hodges, Kevin, Hoskins, Brian J., Shepherd, Theodore G.
Format Journal Article
LanguageEnglish
Published Boston American Meteorological Society 15.03.2019
Subjects
Advection
Algorithms
Anomalies
Atmospheric temperature
Climate change
Cold
Cyclones
Distribution
Global warming
Hemispheric laterality
Perturbation
Skewness
Southern Hemisphere
Storm tracks
Storms
Studies
Surface temperature
Temperature
Temperature anomalies
Temperature distribution
Temperature variability
Tracking
Arctic region
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Summary:The atmospheric temperature distribution is typically described by its mean and variance, while higher-order moments, such as skewness, have received less attention. Skewness is a measure of the asymmetry between the positive and negative tails of the distribution, which has implications for extremes. It was recently shown that near-surface temperature in the Southern Hemisphere is positively skewed on the poleward side of the storm tracks and negatively skewed on the equatorward side. Here we take a dynamical approach to further study what controls the spatial structure of the near-surface temperature distribution in this region. We employ a tracking algorithm to study the formation, intensity, and movement of warm and cold temperature anomalies. We show that warm anomalies are generated on the equatorward side of the storm tracks and propagate poleward, while cold anomalies are generated on the poleward side and propagate equatorward. We further show that while the perturbation growth is mainly achieved through linear meridional advection, it is the nonlinear meridional advection that is responsible for the meridional movement of the temperature anomalies and therefore to the differential skewness. The projected poleward shift and increase of the temperature variance maximum in the Southern Hemisphere under global warming is shown to be composed of a poleward shift and increase in the maximum intensity of both warm and cold anomalies, and a decrease in their meridional displacements. An analytic expression is derived for the nonlinear meridional temperature tendency, which captures the spatial structure of the skewness and its projected changes.
ISSN:0894-8755
1520-0442
DOI:10.1175/JCLI-D-18-0462.1