Radiation, heat, and surface exchange processes

Sharon E. Nicholson

doi:10.1017/CBO9780511973840.009

6 - Radiation, heat, and surface exchange processes

from Part II - The meteorological background

Published online by Cambridge University Press: 05 November 2011

Sharon E. Nicholson

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Sharon E. Nicholson: Affiliation:
Florida State University

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Summary

Introduction

The heating of the earth–atmosphere system is accomplished via the processes of radiation, conduction, convection, and latent heat release. Radiation is energy in the form of electromagnetic waves that propagate through space; the waves travel at the speed of light and require no medium for propagation. Conduction is heat transfer via molecular collision, the essence of the process being an exchange of kinetic energy between molecules. Thus, it is most effective in a solid medium, in which molecules are relatively closely packed. Convection is heat transfer via mixing of parcels in fluids; it is much more rapid than conduction and acts on a larger scale. Since it requires translation of molecules, the convection process is limited to liquids and gases. Latent heat involves the molecular energy related to phase changes of water. For each gram of water, one calorie of heat is required to break the intermolecular bonds in the solid phase and vaporize the water. When water vapor condenses, this amount of heat is released. Thus, heat is transferred from the ground, where water is evaporated, to the atmosphere, where it condenses.

Over the earth as a whole and over time, the radiation received from the sun is largely equivalent to that emitted by the earth and atmosphere. This situation, termed the radiation balance, is required if the earth is to maintain a thermal equilibrium. For any given location, the radiation received at the surface is balanced by the remaining processes of heat transfer. This is referred to as the surface heat or energy balance. Atmospheric and surface characteristics determine the values of each term in the balance. The surface plays a particularly important role because the nature of the ground and the characteristics of the air layer just above it govern the fluxes that determine the heat balance. Latent heating intimately links the heat and water balances.

Type: Chapter
Information: Dryland Climatology , pp. 100 - 114

DOI: https://doi.org/10.1017/CBO9780511973840.009 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2011

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References

Al Nakshabandi, G.Kohnke, H. 1965 Thermal conductivity and diffusivity of soils as related to moisture tension and other physical propertiesAgricultural Meteorology 2 271CrossRef Google Scholar

Aoki, T.Coauthors, 2005 Spectral albedo of desert surfaces measured in western and central ChinaJournal of the Meteorological Society of Japan 83A 279CrossRef Google Scholar

Ba, M. B.Nicholson, S. E.Frouin, R. 2001 Temporal and spatial variability of surface radiation budget over the African continent as derived from METEOSAT. Part II. Temporal and spatial variability of surface global solar irradiance, albedo and net radiationJournal of Climate 14 602.0.CO;2>CrossRef Google Scholar

Charney, J. G. 1975 Dynamics of deserts and drought in the SahelQuarterly Journal of the Royal Meteorological Society 54 642Google Scholar

Coulibaly, Y.Boutin, C. 1983 Estimation des flux de chaleurs sensible et latente en zone ce savane (Cote d’Ivoire)Annales de l’Université d’Abidjan XIX, 79Google Scholar

Deacon, E. L. 1969 Physical processes near the surface of the earthWorld Survey of ClimatologyGoogle Scholar

Dickinson, R. E. 1983 Land surface processes and climate: surface albedos and energy balanceAdvances in Geophysics 25 305CrossRef Google Scholar

Dobos, E. 2006 Encyclopedia of Soil ScienceTaylor & FrancisLondonGoogle Scholar

Durand, P.Frangi, J.-P.Druilhet, A. 1988 Energy budget for Sahel surface layer during the ECLATS ExperimentBoundary-Layer Meteorology 42 27CrossRef Google Scholar

Frangi, J. - P.Druilhet, A.Durand, P.Ide, H.Pages, J. P.Ringa, A. 1992 Energy budget of the Sahelian surface layerAnnales Geophysicae 10 25Google Scholar

Geiger, R. 1965 The Climate Near the GroundHarvard University PressCambridge, MAGoogle Scholar

Idso, S. B.Jackson, R. D.Reginato, R. J.Kimball, B. A.Nakayama, F. S. 1975 The dependence of bare soil albedo on soil water contentJournal of Applied Meteorology 14 1092.0.CO;2>CrossRef Google Scholar

Kabat, P.Dolman, A. J.Elbers, J. A. 1997 Evaporation, sensible heat and canopy conductance of fallow savannah and patterned woodland in the SahelJournal of Hydrology 188/189 494CrossRef Google Scholar

Kaimal, J. C.Finnigan, J. J. 1994 Atmospheric Boundary Layer FlowsOxford University PressNew YorkGoogle Scholar

Kraus, H.Alkhalaf, A. 1995 Characteristic surface energy balances for different climate typesInternational Journal of Climatology 15 275CrossRef Google Scholar

Kustas, W. P.Coauthors, 1991 An interdisciplinary field study of the energy and water fluxes in the atmosphere–biosphere system over semiarid rangelands: description and some preliminary resultsBulletin of the American Meteorological Society 72 16832.0.CO;2>CrossRef Google Scholar

Lancaster, N. 1996 The Physical Geography of AfricaOxford University PressOxfordGoogle Scholar

Lettau, H. H. 1969 Note on aerodynamic roughness-parameter estimation on the basis of roughness element descriptionJournal of Applied Meteorology 8 8282.0.CO;2>CrossRef Google Scholar

Lettau, H. H.Davidson, B. 1957 Exploring the Atmosphere’s First MilePergamon PressNew YorkGoogle Scholar

Lettau, H. H.Lettau, K. 1978 Exploring the World’s Driest ClimateLettau, H. H.Lettau, K.Institute for Environmental Studies, University of WisconsinMadison, WIGoogle Scholar

Menenti, M. 1984 Physical Aspects and Determination of Evaporation in DesertsWageningenNetherlandsGoogle Scholar

Michalek, J. L.Colwell, J. E.Roller, N. E. G.Miller, N. A.Kasischke, E. S.Schlesinger, W. H. 2001 Satellite measurements of albedo and radiant temperature from semi-desert grassland along the Arizona/Sonora borderClimatic Change 48 417CrossRef Google Scholar

Miller, R. L.Slingo, A.Barnard, J. C.Kassianov, E. 2009 Seasonal contrast in the surface energy balance in the SahelJournal of Geophysical Research–Atmospheres 114 00E05CrossRef Google Scholar

Munn, R. E. 1966 Descriptive MicrometeorologyAcademic PressNew YorkGoogle Scholar

Oke, T. R. 1987 Boundary Layer ClimatesHalstedNew YorkGoogle Scholar

Otterman, J. 1974 Baring high-albedo soils by overgrazing: a hypothesized desertification mechanismScience 186 531CrossRef Google Scholar PubMed

Qin, Z.Berliner, P.Karnieli, A. 2002 Micrometeorological modeling to understand the thermal anomaly in the sand dunes across the Israel–Egypt borderJournal of Arid Environments 51 281CrossRef Google Scholar

Raschke, E.Vonder Haar, T. H.Bandeen, W. R.Pasternak, M. 1973 The annual radiation balance of the earth–atmosphere system during 1969–1970 from Nimbus-3 measurementsJournal of the Atmospheric Sciences 30 3412.0.CO;2>CrossRef Google Scholar

Raupach, M. R. 1994 Simplified expressions for vegetation roughness length and zero-plane displacement as functions of canopy height and area indexBoundary-Layer Meteorology 71 211CrossRef Google Scholar

Rosenberg, N. J. 1974 Microclimate: The Biological EnvironmentWiley-InterscienceNew YorkGoogle Scholar

Sellers, W. D. 1965 Physical ClimatologyUniversity of Chicago PressGoogle Scholar

Small, E. E.Kurc, S. A. 2003 Tight coupling between soil moisture and the surface radiation budget in semiarid environments: implications for land–atmosphere interactionsWater Resources Research 39CrossRef Google Scholar

Smith, E. A.Reiter, E. R.Gao, Y. X. 1986 Transition of surface-energy budget in the Gobi Desert between spring and summer seasonsJournal of Climate and Applied Meteorology 25 17252.0.CO;2>CrossRef Google Scholar

Stearns, C. R. 1969 Surface heat budget of the Pampa de la Joya, PeruMonthly Weather Review 97 8602.3.CO;2>CrossRef Google Scholar

Tetzlaff, G. 1974 Die Wärmehaushalt in der zentralen SaharaHanover, Germany113 ppGoogle Scholar

Timouk, F.Coauthors, 2009 Response of surface energy balance to water regime and vegetation development in a Sahelian landscapeJournal of Hydrology 375 178CrossRef Google Scholar

Vehrencamp, J. E. 1953 Experimental investigation of heat transfer at an air–earth interfaceTransactions of the American Geophysical Union 34 22CrossRef Google Scholar

Verhoef, A.Allen, S. J.Lloyd, C. R. 1999 Seasonal variation of surface energy balance over two Sahelian surfacesInternational Journal of Climatology 19 12673.0.CO;2-S>CrossRef Google Scholar

Warner, T. T. 2004 Desert MeteorologyCambridge University PressCambridgeCrossRef Google Scholar