Parameterization of clear sky effective emissivity under surface-based temperature inversion at Dome C and South Pole, Antarctica

For most parts of the year the Antarctic Plateau has a surface temperature inversion with strength c. 20 K. Under such conditions the warmer air at the top of the inversion layer contributes more to the clear sky atmospheric longwave radiation at surface level than does the colder air near the groun...

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Bibliographic Details
Published inAntarctic science Vol. 25; no. 5; pp. 697 - 710
Main Authors Busetto, Maurizio, Lanconelli, Christian, Mazzola, Mauro, Lupi, Angelo, Petkov, Boyan, Vitale, Vito, Tomasi, Claudio, Grigioni, Paolo, Pellegrini, Andrea
Format Journal Article
LanguageEnglish
Published Cambridge, UK Cambridge University Press 01.10.2013
Subjects
Earth, ocean, space
Exact sciences and technology
External geophysics
Meteorology
Physical Sciences
Radiative transfer. Solar radiation
polar regions
South Pole
Antarctica
East Antarctica
PS, Antarctica
Antarctica, East Antarctica, Antarctic Plateau, Dome C
Antarctica, South Pole
radio sounding
downwelling longwave irradiance
BSRN
high Antarctic Plateau
Downward radiation
Emissivity
parametrization
Clear sky
infrared rays
irradiance
Polar region
Temperature reversal
Radio sounding
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Summary:For most parts of the year the Antarctic Plateau has a surface temperature inversion with strength c. 20 K. Under such conditions the warmer air at the top of the inversion layer contributes more to the clear sky atmospheric longwave radiation at surface level than does the colder air near the ground. Hence, it is more appropriate to relate longwave irradiance (LWI) to the top of the inversion layer temperature (Tm) than to the ground level temperature (Tg). Analysis of radio soundings carried out at Dome C and South Pole during 2006–08 shows that the temperature at 400 m above the surface (T400) is a good proxy for Tm and is linearly related to Tg with correlation coefficients greater than 0.8. During summer, radiosonde measurements show almost isothermal conditions, hence T400 still remains a good proxy for the lower troposphere maximum temperature. A methodology is presented to parameterize the clear sky effective emissivity in terms of the troposphere maximum temperature, using ground temperature measurements. The predicted LWI values for both sites are comparable with those obtained using radiative transfer models, while for Dome C the bias of 0.8 W m-2 and the root mean square (RMS) of 6.2 W m-2 are lower than those calculated with previously published parametric equations.
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ISSN:0954-1020
1365-2079
DOI:10.1017/S0954102013000096