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JOURNAL OF GEOPHYSICAL RESEARCH,
VOL. 107, NO. D24,
4796,
doi:10.1029/2002JD002084,
2002
Calculation of actinic fluxes with a coupled atmosphere–snow radiative transfer model
Julia Lee-Taylor
National Center for Atmospheric Research,
Boulder,
Colorado,
USA
Sasha Madronich
National Center for Atmospheric Research,
Boulder,
Colorado,
USA
Abstract
A one-dimensional atmospheric radiative transfer model has been extended to include scattering and absorption by multiple
layers of snow. Empirical values for scattering coefficients for wet and dry snow and for absorption by impurities are derived
from previous observations of snow albedo and irradiance attenuation depth, thus avoiding the uncertainties inherent in modeling
the optical properties of ensembles of individual snow grains. Vertical profiles of spectral actinic flux within the model
snowpack are computed and compared to those of down-welling spectral irradiance. The ratio of these two quantities is a strong
function of solar zenith angle near the snow surface but rapidly approaches ∼0.25 (the isotropic limit) at depths greater
than a few centimeters. Calculated rates of in-snow nitrate (NO3−) photolysis confirm that this process can explain at least part of the enhanced NOx concentrations observed in the atmospheric boundary layer above snow.
Published 28
December
2002.
Index Terms: 0322 Atmospheric Composition and Structure: Constituent sources and sinks; 0360 Atmospheric Composition and Structure: Transmission and scattering of radiation.
Read Full Article (file size: 348134 bytes) Cited by
Citation: Lee-Taylor, J., and S. Madronich
(2002),
Calculation of actinic fluxes with a coupled atmosphere–snow radiative transfer model,
J. Geophys. Res.,
107(D24),
4796,
doi:10.1029/2002JD002084.
Copyright 2002 by the American Geophysical Union.
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