On the vertical profile of surface radiative fluxes in southwest Germany

Vertical profile of surface radiative fluxes in an area of heterogeneous terrain in south-west Germany is presented. Main data sets utilized for the study were recorded during the REgio KLIma Projekt (REKLIP). Supporting observational data were provided by the German weather service and German geoph...

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Veröffentlicht in:	Meteorology and atmospheric physics 2002-04, Vol.79 (3-4), p.159-172
Hauptverfasser:	IZIOMON, M. G, MAYER, H, WICKE, W
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Sprache:	eng
Schlagworte:	Albedo Atmosphere Earth, ocean, space Elevation Exact sciences and technology External geophysics Meteorology Radiative transfer. Solar radiation Solar radiation Temperature Terrestrial radiation
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creator	IZIOMON, M. G MAYER, H WICKE, W
description	Vertical profile of surface radiative fluxes in an area of heterogeneous terrain in south-west Germany is presented. Main data sets utilized for the study were recorded during the REgio KLIma Projekt (REKLIP). Supporting observational data were provided by the German weather service and German geophysical consultant service. Elevation of the study sites ranged from 212 m a.s.l. to 1489 m a.s.l. From May to September, monthly mean albedo was generally low at the study sites, ranging from 19% to 24%. For the other months, monthly mean albedo lie between 22% and 25% at the lowland site but extended between 27% and 71% at the highly elevated mountain site. Following the altitudinal increase in surface albedo, net radiative flux and radiation efficiency declined with elevation at an annual mean of 1.15 Wmm2/100 m and 0.008/100 m respectively. Absorbed shortwave radiation and effective terrestrial radiation showed mean decline of 1.54 Wmm2/100 m and 0.34 Wmm2/100 m, respectively, with the mean sky-to-earth radiation deficit amounting to about 52 Wmm2 for the lowland site and 73 Wmm2 for the highest elevated site. Some empirical models which express shortwave and longwave radiative fluxes in terms of meteorological variables have been validated for the lowland and mountain sites. Monthly mean daily total estimates of solar radiation obtained from Aringngstm-Prescott relation were quite consistent with observed values. Parameterisation of downward atmospheric radiation under all sky condition was achieved by extending Brutsaert clear sky atmospheric model. Relationship between outgoing longwave radiation and screen temperature at the study sites was best described by an exponential function unlike the linear relationship proposed by Monteith and Unsworth. Net radiative flux for the lowland and mountain sites has been expressed in terms of absorbed shortwave radiation, cloud amount and screen temperature. [PUBLICATION ABSTRACT]
doi_str_mv	10.1007/s007030200001
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Parameterisation of downward atmospheric radiation under all sky condition was achieved by extending Brutsaert clear sky atmospheric model. Relationship between outgoing longwave radiation and screen temperature at the study sites was best described by an exponential function unlike the linear relationship proposed by Monteith and Unsworth. Net radiative flux for the lowland and mountain sites has been expressed in terms of absorbed shortwave radiation, cloud amount and screen temperature. [PUBLICATION ABSTRACT]</abstract><cop>Wien</cop><cop>New York, NY</cop><pub>Springer</pub><doi>10.1007/s007030200001</doi><tpages>14</tpages></addata></record>
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subjects	Albedo Atmosphere Earth, ocean, space Elevation Exact sciences and technology External geophysics Meteorology Radiative transfer. Solar radiation Solar radiation Temperature Terrestrial radiation
title	On the vertical profile of surface radiative fluxes in southwest Germany
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