Using ‘heat tagging’ to understand the remote influence of atmospheric diabatic heating through long-range transport

In the circulating atmosphere, diabatic heating influences the potential temperature content of air masses far from where the heating occurs. Budgets that balance local diabatic sources with local heat divergence and storage do not retain information about this remote influence, which requires air-m...

Full description

Saved in:
Bibliographic Details
Published in:Journal of the atmospheric sciences 2021-07, Vol.78 (7), p.2161
Main Authors: Fajber, Robert, Kushner, Paul J.
Format: Article
Language:English
Subjects:
Air masses
Air temperature
Atmosphere
Atmospheric circulation
Diabatic heating
Energy transport
Enthalpy
ENVIRONMENTAL SCIENCES
global transport modeling
Heat
Heat transport
Heating
Hydrologic cycle
Hydrological cycle
Hydrology
Long-range transport
Marking
mass fluxes/transport
Potential temperature
Radiative heating
Sensible heat
Storage
Storm tracks
Storms
Stratosphere
Tags
Temperature
Tracers
Tracking
Tropical environments
Troposphere
Variability
Water vapor
Water vapour
Citations: Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:In the circulating atmosphere, diabatic heating influences the potential temperature content of air masses far from where the heating occurs. Budgets that balance local diabatic sources with local heat divergence and storage do not retain information about this remote influence, which requires air-mass tracking. In this study, a process based, passive-tracer diagnostic, called heat tagging , is introduced. Heat tagging locally decomposes the potential temperature into contributions from the distinctive diabatic processes that generate them, wherever they occur. The distribution, variability and transport of atmospheric heat tags are studied in the relatively simple setting of an idealized aquaplanet model. Heat tags from latent heating are generated in the deep tropics and the midlatitude storm track and then transported throughout the troposphere. By contrast dry sensible heat tags are enhanced near the surface, and radiative tags are mainly confined to the stratosphere. As a result, local heat transport, variability of potential temperature and global poleward heat transport are dominated by heat tags related to latent heating, with heat tags from sensible and radiative heating only making contributions in the polar near surface and the stratosphere respectively. Heat tagging thus quantifies how water vapor and latent heating link the structural characteristics of the atmosphere and illustrates the importance of the hydrological cycle in poleward energy transport.
ISSN:0022-4928
1520-0469
DOI:10.1175/JAS-D-20-0290.1