The Landsat Scale Break in Stratocumulus as a Three-Dimensional Radiative Transfer Effect: Implications for Cloud Remote Sensing

Several studies have uncovered a break in the scaling properties of Landsat cloud scenes at nonabsorbing wavelengths. For scales greater than 200‐400 m, the wavenumber spectrum is approximately power law in k25/3, but from there down to the smallest observable scales (50‐100 m) follows another k2b law with b . 3. This implies very smooth radiance fields. The authors reexamine the empirical evidence for this scale break and explain it using fractal cloud models, Monte Carlo simulations, and a Green function approach to multiple scattering theory. In particular, the authors define the ‘‘radiative smoothing scale’’ and relate it to the characteristic scale of horizontal photon transport. The scale break was originally thought to occur at a scale commensurate with either the geometrical thickness Dz of the cloud, or with the ‘‘transport’’ mean free path lt 5 [(1 2 g)s]21, which incorporates the effect of forward scattering (s is extinction and g the asymmetry factor of the phase function). The smoothing scale is found to be approximately ltDz at cloud top; this is the prediction of diffusion ˇ theory which applies when (1 2 g)t 5D z / l t * 1( tis optical thickness). Since the scale break is a tangible effect of net horizontal radiative fluxes excited by the fluctuations of t, the smoothing scale sets an absolute lower bound on the range where one can neglect these fluxes and use plane-parallel theory locally, even for stratiform clouds. In particular, this constrains the retrieval of cloud properties from remotely sensed data. Finally, the characterization of horizontal photon transport suggests a new lidar technique for joint measurements of optical and geometrical thicknesses at about 0.5-km resolution.

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

[2]  L. C. Henyey,et al.  Diffuse radiation in the Galaxy , 1940 .

[3]  S. Corrsin On the Spectrum of Isotropic Temperature Fluctuations in an Isotropic Turbulence , 1951 .

[4]  R. A. Silverman,et al.  Wave Propagation in a Turbulent Medium , 1961 .

[5]  R. Kraichnan Inertial Ranges in Two‐Dimensional Turbulence , 1967 .

[6]  A. Obukhov,et al.  Structure of Temperature Field in Turbulent Flow , 1970 .

[7]  J. Weinman,et al.  The effect of atmospheric haze on images of the Earth's surface , 1975 .

[8]  R. S. Fraser,et al.  Adjacency effects on imaging by surface reflection and atmospheric scattering: cross radiance to zenith. , 1979, Applied optics.

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

[10]  W. King,et al.  Further Performance Tests on the CSIRO Liquid Water Probe. , 1981 .

[11]  P. Deschamps,et al.  Influence of the background contribution upon space measurements of ground reflectance. , 1981, Applied optics.

[12]  S. Lovejoy Area-Perimeter Relation for Rain and Cloud Areas , 1982, Science.

[13]  D. Diner,et al.  Atmospheric transfer of radiation above an inhomogeneous non-Lambertian reflective ground—I. Theory , 1984 .

[14]  D. Diner,et al.  Atmospheric transfer of radiation above an inhomogeneous non-Lambertian reflective ground. II. Computational considerations and results. , 1984 .

[15]  Radiative transfer in spatially heterogeneous, two-dimensional, anisotropically scattering media , 1986 .

[16]  Ronald M. Welch,et al.  Cumulus Cloud Properties Derived Using Landsat Satellite Data , 1986 .

[17]  C. Meneveau,et al.  Simple multifractal cascade model for fully developed turbulence. , 1987, Physical review letters.

[18]  D. Schertzer,et al.  Physical modeling and analysis of rain and clouds by anisotropic scaling multiplicative processes , 1987 .

[19]  G. Stephens Radiative Transfer through Arbitrarily Shaped Optical Media. Part II. Group Theory and Simple Closures , 1988 .

[20]  S. Sengupta,et al.  Marine Stratocumulus Cloud Fields off the Coast of Southern California Observed Using LANDSAT Imagery. Part I: Structural Characteristics , 1988 .

[21]  ANALYSE DES EFFETS ATMOSPHÉRIQUES DANS LES IMAGES HRV DE SPOT , 1988 .

[22]  K. Stamnes,et al.  Numerically stable algorithm for discrete-ordinate-method radiative transfer in multiple scattering and emitting layered media. , 1988, Applied optics.

[23]  Robert F. Cahalan,et al.  Marine stratocumulus structure , 1989 .

[24]  Robert F. Cahalan,et al.  Fractal Statistics of Cloud Fields , 1989 .

[25]  Michael D. King,et al.  Determination of the Spectral Absorption of Solar Radiation by Marine Stratocumulus Clouds from Airborne Measurements within Clouds , 1990 .

[26]  D. Schertzer,et al.  Continuous Multiplicative Cascade Models of Rain and Clouds , 1991 .

[27]  Howard W. Barker,et al.  Cumulus cloud radiative properties and the characteristics of satellite radiance wavenumber spectra , 1992 .

[28]  Daniel Schertzer,et al.  The unified scaling model of atmospheric dynamics and systematic analysis of scale invariance in cloud radiances : Nonlinear processes in geophysics , 1993 .

[29]  Bruce A. Wielicki,et al.  The interpretation of remotely sensed cloud properties from a model paramterization perspective , 1994 .

[30]  Robert F. Cahalan,et al.  The albedo of fractal stratocumulus clouds , 1994 .

[31]  Robert F. Cahalan,et al.  Bounded cascade models as nonstationary multifractals. , 1994, Physical review. E, Statistical physics, plasmas, fluids, and related interdisciplinary topics.

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

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

[34]  Anthony B. Davis,et al.  Multifractal characterizations of nonstationarity and intermittency in geophysical fields: Observed, retrieved, or simulated , 1994 .

[35]  B. Chance,et al.  Spectroscopy and Imaging with Diffusing Light , 1995 .

[36]  Anthony B. Davis,et al.  Radiative smoothing in fractal clouds , 1995 .

[37]  David M. Winker,et al.  An overview of LITE: NASA's Lidar In-space Technology Experiment , 1996, Proc. IEEE.

[38]  David M. Winker,et al.  Retrieval of Physical and Optical Cloud Thicknesses from Space-Borne and Wide-Angle Imaging Lidar , 1997 .