Abstract
Abstract. A 7-year (2010–2016) comparison study between measured and simulated longwave downward radiation (LDR) under cloud-free conditions was performed at the Izaña Atmospheric Observatory (IZO, Spain). This analysis encompasses a total of 2062 cases distributed approximately evenly between day and night. Results show an excellent agreement between Baseline Surface Radiation Network (BSRN) measurements and simulations with libRadtran V2.0.1 and MODerate resolution atmospheric TRANsmission model (MODTRAN) V6 radiative transfer models (RTMs). Mean bias (simulated − measured) of < 1.1 % and root mean square of the bias (RMS) of < 1 % are within the instrumental error (2 %). These results highlight the good agreement between the two RTMs, proving to be useful tools for the quality control of LDR observations and for detecting temporal drifts in field instruments. The standard deviations of the residuals, associated with the RTM input parameters uncertainties are rather small, 0.47 and 0.49 % for libRadtran and MODTRAN, respectively, at daytime, and 0.49 to 0.51 % at night-time. For precipitable water vapor (PWV) > 10 mm, the observed night-time difference between models and measurements is +5 W m−2 indicating a scale change of the World Infrared Standard Group of Pyrgeometers (WISG), which serves as reference for atmospheric longwave radiation measurements. Preliminary results suggest a possible impact of dust aerosol on infrared radiation during daytime that might not be correctly parametrized by the models, resulting in a slight underestimation of the modeled LDR, of about −3 W m−2, for relatively high aerosol optical depth (AOD > 0.20).
Highlights
Longwave downward radiation (LDR) at the Earth’s surface is a key component in land–atmosphere interaction processes, and is crucial in surface energy budget and global climate change, because the changes in the longwave downward radiation (LDR) values may be related to changes in cloud cover, cloud type, water vapor, temperature and the increase of anthropogenic greenhouse gas concentrations in the atmosphere (Wild et al, 1997; Marty et al, 2003; Iacono et al, 2008; Philipona et al, 2012; Wild et al, 2013; Wang and Dickinson, 2013; Wild et al, 2015)
The Izaña Atmospheric Observatory (IZO, http://izana.aemet.es, last access: 28 November 2017) is an optimal station to carry out this study, because all the model input parameters (PWV, precipitable water vapor; AOD, aerosol optical depth; total ozone; in situ N2O; in situ CO2; CO2 profiles; meteorological radiosondes) are measured at the station
We present the comparison between LDR measured with Baseline Surface Radiation Network (BSRN) and simulated with libRadtran and MODTRAN, considering the available and coincident cloudfree BSRN at daytime and night-time, and the inputs indicated in Sect. 4 at IZO between 2010 and 2016
Summary
Longwave downward radiation (LDR) at the Earth’s surface is a key component in land–atmosphere interaction processes, and is crucial in surface energy budget and global climate change, because the changes in the LDR values may be related to changes in cloud cover, cloud type, water vapor, temperature and the increase of anthropogenic greenhouse gas concentrations in the atmosphere (Wild et al, 1997; Marty et al, 2003; Iacono et al, 2008; Philipona et al, 2012; Wild et al, 2013; Wang and Dickinson, 2013; Wild et al, 2015). García et al.: Comparison of observed and modeled LDR at BSRN Izaña
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