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Estimation of SW flux absorbed at the surface from TOA reflected flux. [TOA (top of the atmosphere)]

Journal Article · · Journal of Climate; (United States)
;  [1]; ;  [2]
  1. McGill Univ., Montreal, Quebec (Canada)
  2. Meteorological Research Institute, Tsukuba, Ibaraki (Japan)
+ Show Author Affiliations
Measurements of radiation budgets, both at the top of the atmosphere (TOA) and at the surface, are essential to understanding the earth's climate. The TOA budgets can, in principle, be measured directly from satellites, while on a global scale surface budgets need to be deduced from TOA measurements. Most methods of inferring surface solar-radiation budgets from satellite measurements are applicable to particular scene types or geographic locations, and none is valid over highly reflective surfaces such as ice or snow. In addition, the majority of models require inputs such as cloud-optical thickness that are usually not known. Extensive radiative transfer modeling for different surface, atmospheric, and cloud conditions suggests a linear relationship between the TOA-reflected flux and the flux absorbed at the surface for a fixed solar zenith angle (SZA). The linear relationship is independent of cloud-optical thickness and surface albeds. Sensitivity tests show that the relationship depends strongly on SZA and moderately on precipitable water and cloud type. The linear relationship provides a simple parameterization to estimate surface-absorbed flux from satellite-measured reflected flux at the TOA. Unlike other models, the present model makes explicit use of the SZA. Precipitable water is included as a secondary parameter. Surface-absorbed fluxes deduced from this simple parameterized model generally agree to within 10 W m-[close quote] with the absorbed fluxes determined from detailed radiative transfer calculations, without including information on the presence or absence of cloud, cloud type, optical thickness, or surface type.
OSTI ID:
6575339
Journal Information:
Journal of Climate; (United States), Journal Name: Journal of Climate; (United States) Vol. 6:2; ISSN JLCLEL; ISSN 0894-8755
Country of Publication:
United States
Language:
English

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Related Subjects

54 ENVIRONMENTAL SCIENCES
540110*
ALBEDO
ATMOSPHERIC PRECIPITATIONS
CLIMATE MODELS
CLOUDS
COMPUTER CALCULATIONS
EARTH ATMOSPHERE
ENERGY BUDGETS
ICE
MATHEMATICAL MODELS
RADIATIONS
SATELLITES
SENSITIVITY
SNOW
SOLAR RADIATION
STELLAR RADIATION