Abstract
Abstract. Clouds cover around two thirds of the Earth’s surface. Most of them are thick enough to influence the radiative budget of our planet: they increase the top of atmosphere (TOA) exitance and they alter the bottom of atmosphere (BOA) direct and diffuse irradiance. However, most radiative transfer models dedicated to Earth surfaces, such as DART (Discrete Anisotropic Radiative Transfer), simulate only cloudless atmospheres. We recently introduced clouds in DART in order to improve the modelling of weather for remote sensing simulations. In this implementation, clouds were characterized with user specified optical properties and vertical distribution. They were modelled as layered one-dimensional medium that coexists with gases and aerosols. The atmospheric radiative transfer modelling relies on the discrete ordinate method already in DART. In addition, an iterative inversion procedure was designed to test this improvement with field measurements during two cloudy days at Lamasquère meteorological station (France). Specifically, it derives time-series of atmosphere parameters from time-series of BOA solar irradiance measurements. These inversed atmospheric parameters were used to simulate total and diffuse BOA irradiance in PAR (Photosynthetically Active Radiation) domain. The comparison of time-series of measured and DART simulated PAR irradiance lead to very encouraging results (mean relative error ∼8% for total irradiance and ∼20% for diffuse irradiance). It stresses the potential of DART to accurately simulate irradiance in cloudy days.
Highlights
With the objectives to (1) assess the validity of the new DART cloud modelling and to (2) make use of the measured broadband data in practical applications, we investigated to simulate the time-series of bottom of atmosphere (BOA) direct E"#$,Bf3,&$'((λ, t) and diffuse E"#$,Bfgg,&$'((λ, t) irradiance for any spectral band (λ, Δλ) with atmosphere parameters derived from E"#$,./0123/(t) using a DART-based atmospheric inversion procedure (Figure 2)
The validation was conducted with instantaneous values of irradiance measured every 30 minutes of the day by a meteorological station located at Lamasquère (43°29’47’’N, 1°14’16’’E, 180-m average elevation in Haute-Garonne department, France)
We considered time-series of BOA irradiance in both solar (0.4 μm – 2.7 μm) and PAR (Photosynthetically Active Radiation, 0.4 μm – 0.7 μm) domain acquired on July 14, 2016 and August 18, 2016
Summary
Clouds are one of the most common weather phenomena that greatly influence optical remote sensing (RS) observations. Their global coverage with an optical depth larger than 0.1 is ~ 68%, with an optical depth larger than 2.0 is ~ 56% (Stubenrauch et al 2013). Most clouds are thick enough to strongly influence the top (TOA) and bottom (BOA) of atmosphere irradiance. We designed a cloud modelling method in DART model for simulating accurate direct and diffuse irradiance in cloudy days. Clouds are simulated as layered one-dimensional medium that suspend in the atmosphere in order to adapt to current DART atmospheric RT modelling
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