Abstract
Abstract. The aim of this study is to determine cloud-type resolved cloud radiative budgets and cloud radiative effects from surface measurements of broadband radiative fluxes over the Atlantic Ocean. Furthermore, based on simultaneous observations of the state of the cloudy atmosphere, a radiative closure study has been performed by means of the ECHAM5 single column model in order to identify the model's ability to realistically reproduce the effects of clouds on the climate system. An extensive database of radiative and atmospheric measurements has been established along five meridional cruises of the German research icebreaker Polarstern. Besides pyranometer and pyrgeometer for downward broadband solar and thermal radiative fluxes, a sky imager and a microwave radiometer have been utilized to determine cloud fraction and cloud type on the one hand and temperature and humidity profiles as well as liquid water path for warm non-precipitating clouds on the other hand. Averaged over all cruise tracks, we obtain a total net (solar + thermal) radiative flux of 144 W m−2 that is dominated by the solar component. In general, the solar contribution is large for cirrus clouds and small for stratus clouds. No significant meridional dependencies were found for the surface radiation budgets and cloud effects. The strongest surface longwave cloud effects were shown in the presence of low level clouds. Clouds with a high optical density induce strong negative solar radiative effects under high solar altitudes. The mean surface net cloud radiative effect is −33 W m−2. For the purpose of quickly estimating the mean surface longwave, shortwave and net cloud effects in moderate, subtropical and tropical climate regimes, a new parameterisation was created, considering the total cloud amount and the solar zenith angle. The ECHAM5 single column model provides a surface net cloud effect that is more cooling by 17 W m−2 compared to the radiation observations. This overestimation in solar cooling is mostly caused by the shortwave impact of convective clouds. The latter show a large overestimation in solar cooling of up to 114 W m−2. Mean cloud radiative effects of cirrus and stratus clouds were simulated close to the observations.
Highlights
Shortwave (SW) and longwave (LW) radiation are the main components of the Earth’s energy budget
It would be beneficial for global climate analysis to apply the observed cloud radiative budgets and cloud radiative effects to other regions. To this end we developed a parameterisation of the CRE based on standard synoptical observations as they are available from e.g. the International Comprehensive Ocean-Atmosphere Data Set (ICOADS)
In this study we present a detailed quantification of surface cloud radiative effects for the LW, SW and total spectral range
Summary
Shortwave (SW) and longwave (LW) radiation are the main components of the Earth’s energy budget. The total net radiative flux (radiative budget) is defined as the sum of downward SW radiation (DSR, FDSR), downward LW radiation (DLR, FDLR), outgoing SW radiation (OSR, FOSR) and outgoing LW radiation (OLR, FOLR). DSR, DLR and OSR are strongly influenced by clouds. Clouds cause opposing SW and LW effects. The SW scattering and absorption by clouds depend on the solar zenith angle, the cloud cover, the cloud type, the condition of aggregation of the cloud particles as well as the cloud shape, vertical extension and optical density generally causing a surface shading. Broken clouds can lead to occasional, strong, short-term enhancements of the surface DSR (Schade et al, 2007). In the LW spectra, clouds absorb the surface OLR and re-emit DLR that contributes to the total greenhouse effect
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