Kinetic energy generation in heat engines and heat pumps the relationship between surface pressure temperature and circulation cell size
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Authors
Makarieva, A. M
Gorshkov, V. G
Nefiodov, A. V
Sheil, D
Nobre, A. D
Shearman, Philip
Li, B. -L
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Swedish Geophysical Society: Munksgaard
Abstract
The pattern and size of the Earth’s atmospheric circulation cells determine regional climates and challenge theorists.
Here the authors present a theoretical framework that relates the size of meridional cells to the kinetic energy generation
within them. Circulation cells are considered as heat engines (or heat pumps) driven by surface gradients of pressure and
temperature. This approach allows an analytical assessment of kinetic energy generation in the meridional cells from the
known values of surface pressure and temperature differences across the cell, Δps and ΔTs. Two major patterns emerge.
First, the authors find that kinetic energy generation in the upper and lower atmosphere respond in contrasting ways to
surface temperature: with growing ΔTs, kinetic energy generation increases in the upper atmosphere but declines in the
lower. A requirement that kinetic energy generation must be positive in the lower atmosphere can limit the poleward cell
extension of the Hadley cells via a relationship between Δps and ΔTs. The limited extent of the Hadley cells necessitates
the appearance of heat pumps (Ferrel cells) – circulation cells with negative work output. These cells consume the
positive work output of the Hadley cells (heat engines) and can in theory drive the global efficiency of an axisymmetric
atmospheric circulation down to zero. Second, the authors show that, within a cell, kinetic energy generation is largely
determined by ΔTs in the upper atmosphere, and by Δps in the lower. By absolute magnitude, the temperature
contribution is about 10 times larger. However, since the heat pumps act as sinks of kinetic energy in the upper
atmosphere, the net kinetic energy generation in the upper atmosphere, as well as the net impact of surface temperature,
is reduced. The authors use NCAR/NCEP and MERRA data to verify the obtained theoretical relationships. These
observations confirm considerable cancellation between the temperature-related sources and sinks of kinetic energy in
the upper atmosphere. Both the theoretical approach and observations highlight a major contribution from surface
pressure gradients, rather than temperature, in the kinetic energy budget of meridional circulation. The findings urge
increased attention to surface pressure gradients as determinants of the meridional circulation patterns.
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Tellus, Series A: Dynamic Meteorology and Oceanography
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Open Access
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