Can energy fluxes be used to interpret glacial/interglacial precipitation changes in the tropics?

Abstract Recent theoretical advances in the relationship between heat transport and the position of the Intertropical Convergence Zone (ITCZ) present an elegant framework through which to interpret past changes in tropical precipitation patterns. Using a very large ensemble of climate model simulati...

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Bibliographic Details
Published in:Geophysical research letters 2017-06, Vol.44 (12), p.6373-6382
Main Authors: Roberts, W. H. G., Valdes, P. J., Singarayer, J. S.
Format: Article
Language:English
Subjects:
Annual variations
Atmospheric precipitations
Atmospheric pressure
Boundary conditions
Circulation
Climate
Climate models
Climatology
Computer simulation
Convergence
Convergence zones
Energy
Energy transfer
Energy transport
Equator
Equatorial regions
Evolution
Fluxes
Frameworks
Glaciers
Hadley circulation
Heat
Heat transport
Hemispheres
Insolation
Interglacial periods
Intertropical convergence zone
Loads (forces)
Local precipitation
Meridional heat transport
Paleoprecipitation
Position (location)
Precipitation
Precipitation patterns
Rain
Rainfall
Records
Seasonal variation
Temperature
Temperature effects
Transport
Tropical climate
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Summary:Abstract Recent theoretical advances in the relationship between heat transport and the position of the Intertropical Convergence Zone (ITCZ) present an elegant framework through which to interpret past changes in tropical precipitation patterns. Using a very large ensemble of climate model simulations, we investigate whether it is possible to use this framework to interpret changes in the position of the ITCZ in response to glacial and interglacial boundary conditions. We find that the centroid of tropical precipitation, which represents the evolution of precipitation in the whole tropics, is best correlated with heat transport changes. We find that the response of the annual mean ITCZ to glacial and interglacial boundary conditions is quite different to the response of the climatological annual cycle of the ITCZ to the seasonal cycle of insolation. We show that the reason for this is that while the Hadley Circulation plays a dominant role in transporting heat over the seasonal cycle, in the annual mean response to forcing, the Hadley Circulation is not dominant. When we look regionally, rather than at the zonal mean, we find that local precipitation is poorly related either to the zonal mean ITCZ or to meridional heat transport. We demonstrate that precipitation is spatially highly variable even when the zonal mean ITCZ is in the same location. This suggests only limited use for heat transport in explaining local precipitation records; thus, there is limited scope for using heat transport changes to explain individual paleoprecipitation records. Plain Language Summary How energy is moved across the equator is important in determining how the temperature of the Northern and Southern Hemispheres differ. Recent theory has suggested that this energy transport can be related to the rainfall in the tropics. Understanding how the global temperature and the rainfall are related is an important question for understanding the climate of the past and the future. To understand the relationship between rainfall and heat transport in the past and future, it had been assumed that it was possible to use the relationship between them over the seasonal cycle in the modern day as a template. In this paper we show that this is not the case. To understand how rainfall and energy are related in the past and future will require additional theory. One implication of this is that we must be very careful when assessing records of rainfall from the past, not to use our intuition f
ISSN:0094-8276
1944-8007
DOI:10.1002/2017GL073103