Reduction of radiation biases by incorporating the missing cloud variability by means of downscaling techniques: a study using the 3-D MoCaRT model

Abstract. Handling complexity to the smallest detail in atmospheric radiative transfer models is unfeasible in practice. On the one hand, the properties of the interacting medium, i.e., the atmosphere and the surface, are only available at a limited spatial resolution. On the other hand, the computational cost of accurate radiation models accounting for three-dimensional heterogeneous media are prohibitive for some applications, especially for climate modelling and operational remote-sensing algorithms. Hence, it is still common practice to use simplified models for atmospheric radiation applications. Three-dimensional radiation models can deal with complex scenarios providing an accurate solution to the radiative transfer. In contrast, one-dimensional models are computationally more efficient, but introduce biases to the radiation results. With the help of stochastic models that consider the multi-fractal nature of clouds, it is possible to scale cloud properties given at a coarse spatial resolution down to a higher resolution. Performing the radiative transfer within the cloud fields at higher spatial resolution noticeably helps to improve the radiation results. We present a new Monte Carlo model, MoCaRT, that computes the radiative transfer in three-dimensional inhomogeneous atmospheres. The MoCaRT model is validated by comparison with the consensus results of the Intercomparison of Three-Dimensional Radiation Codes (I3RC) project. In the framework of this paper, we aim at characterising cloud heterogeneity effects on radiances and broadband fluxes, namely: the errors due to unresolved variability (the so-called plane parallel homogeneous, PPH, bias) and the errors due to the neglect of transversal photon displacements (independent pixel approximation, IPA, bias). First, we study the effect of the missing cloud variability on reflectivities. We will show that the generation of subscale variability by means of stochastic methods greatly reduce or nearly eliminate the reflectivity biases. Secondly, three-dimensional broadband fluxes in the presence of realistic inhomogeneous cloud fields sampled at high spatial resolutions are calculated and compared to their one-dimensional counterparts at coarser resolutions. We found that one-dimensional calculations at coarsely resolved cloudy atmospheres systematically overestimate broadband reflected and absorbed fluxes and underestimate transmitted ones.

[1]  Observations of Three-Dimensional Radiative Effects That Influence Satellite Retrievals of Cloud Properties , 2013 .

[2]  B. Mayer,et al.  Validation of cloud property retrievals with simulated satellite radiances: a case study for SEVIRI , 2010 .

[3]  Bjorn Stevens,et al.  A Large-Eddy Simulation Study of Anisotropy in Fair-Weather Cumulus Cloud Fields , 2005 .

[4]  Steven Platnick,et al.  Viewing Geometry Dependencies in MODIS Cloud Products , 2010 .

[5]  Robert L. Kurucz,et al.  The Solar Spectrum: Atlases and Line Identifications , 1995 .

[6]  C. Simmer,et al.  A new algorithm for the downscaling of cloud fields , 2010 .

[7]  M. King,et al.  Determination of the optical thickness and effective particle radius of clouds from reflected solar , 1990 .

[8]  Jean-Christophe Golaz,et al.  Large‐eddy simulation of the diurnal cycle of shallow cumulus convection over land , 2002 .

[9]  William B. Rossow,et al.  Calculation of surface and top of atmosphere radiative fluxes from physical quantities based on ISCCP data sets: 2. Validation and first results , 1995 .

[10]  Q. Fu,et al.  On the correlated k-distribution method for radiative transfer in nonhomogeneous atmospheres , 1992 .

[11]  R. Reynolds,et al.  Bulletin of the American Meteorological Society , 1996 .

[12]  A. Żarnecki Global analysis of , 1999, hep-ph/9904334.

[13]  Paul W. Stackhouse,et al.  The Effect of Cumulus Cloud Field Anisotropy on Domain-Averaged Solar Fluxes and Atmospheric Heating Rates , 2007 .

[14]  Anthony B. Davis,et al.  3D Radiative Transfer in Cloudy Atmospheres , 2005 .

[15]  B. Mayer,et al.  Remote sensing of stratocumulus clouds: Uncertainties and biases due to inhomogeneity , 2006 .

[16]  B. P. Watson,et al.  Scattering in thick multifractal clouds, Part I: Overview and single scattering , 2009 .

[17]  Robert F. Cahalan,et al.  The I3RC - Bringing Together the Most Advanced Radiative Transfer Tools for Cloudy Atmospheres , 2005 .

[18]  Boris A. Kargin,et al.  The Monte Carlo Methods in Atmospheric Optics , 1980 .

[19]  C. Gautier,et al.  A Three-Dimensional Radiative Transfer Model to Investigate the Solar Radiation within a Cloudy Atmosphere. Part II: Spectral Effects , 1998 .

[20]  Bernhard Mayer,et al.  Efficient unbiased variance reduction techniques for Monte Carlo simulations of radiative transfer in cloudy atmospheres: The solution , 2011 .

[21]  Robert F. Cahalan Bounded cascade clouds: albedo and effective thickness , 1994 .

[22]  A. Slingo A GCM Parameterization for the Shortwave Radiative Properties of Water Clouds , 1989 .

[23]  Frank S. Marzano,et al.  Spectral Downscaling of Integrated Water Vapor Fields From Satellite Infrared Observations , 2012, IEEE Transactions on Geoscience and Remote Sensing.

[24]  Anthony B. Davis,et al.  Nonlocal independent pixel approximation: direct and inverse problems , 1998, IEEE Trans. Geosci. Remote. Sens..

[25]  D. Deirmendjian Scattering and Polarization Properties of Water Clouds and Hazes in the Visible and Infrared , 1964 .

[26]  Ann Henderson-Sellers,et al.  Surface albedo data for climatic modeling , 1983 .

[27]  Anke Kniffka,et al.  Combining the independent pixel and point-spread function approaches to simulate the actinic radiation field in moderately inhomogeneous 3D cloudy media , 2011 .

[28]  Thomas Trautmann,et al.  Surrogate cloud fields generated with the iterative amplitude adapted Fourier transform algorithm , 2006 .

[29]  A. Tompkins,et al.  Effect of Spatial Organization on Solar Radiative Transfer in Three-Dimensional Idealized Stratocumulus Cloud Fields , 2003 .

[30]  B. P. Watson,et al.  Scattering in thick multifractal clouds, Part II: Multiple scattering , 2009 .

[31]  Alexander Marshak,et al.  Observations of Three-Dimensional Radiative Effects that Influence MODIS Cloud Optical Thickness Retrievals , 2002 .

[32]  H. Barker A parameterization for computing grid-averaged solar fluxes for inhomogeneous marine boundary layer , 1996 .

[33]  E. Shettle,et al.  Models for the aerosols of the lower atmosphere and the effects of humidity variations on their optical properties , 1979 .

[34]  Roger Davies,et al.  Plane Parallel Albedo Biases from Satellite Observations. Part I: Dependence on Resolution and Other Factors , 1998 .

[35]  K. Evans The Spherical Harmonics Discrete Ordinate Method for Three-Dimensional Atmospheric Radiative Transfer , 1998 .

[36]  P. Koepke,et al.  Optical Properties of Aerosols and Clouds: The Software Package OPAC , 1998 .

[37]  Brian Cairns,et al.  Absorption within inhomogeneous clouds and its parameterization in general circulation models , 2000 .

[38]  M. King,et al.  Determination of the Optical Thickness and Effective Particle Radius of Clouds from Reflected Solar Radiation Measurements. Part II: Marine Stratocumulus Observations , 1991 .

[39]  M. King Determination of the Scaled Optical Thickness of Clouds from Reflected Solar Radiation Measurements , 1987 .

[40]  Robert F. Cahalan,et al.  Independent Pixel and Monte Carlo Estimates of Stratocumulus Albedo , 1994 .

[41]  Rhys Goldstein,et al.  Monte Carlo Simulation of Solar Reflectances for Cloudy Atmospheres , 2003 .

[42]  V. Derr,et al.  Remote sensing of the lower atmosphere , 1971 .

[43]  J. Jensen Sur les fonctions convexes et les inégalités entre les valeurs moyennes , 1906 .

[44]  R. Bar-Or,et al.  Global analysis of cloud field coverage and radiative properties, using morphological methods and MODIS observations , 2010 .

[45]  M. Nicolet,et al.  On the molecular scattering in the terrestrial atmosphere : An empirical formula for its calculation in the homosphere , 1984 .

[46]  A. Marshak,et al.  Solar radiation transport in the cloudy atmosphere: a 3D perspective on observations and climate impacts , 2010 .

[47]  Roger Davies,et al.  Effects of Cloud Heterogeneities on Shortwave Radiation: Comparison of Cloud-Top Variability and Internal Heterogeneity , 1999 .