| The Open Atmospheric
Science Journal
ISSN: 1874-2823
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[DOI: 10.2174/1874282300802010046]
Development and Evaluation of a Simple Algorithm to Find
Cloud Optical Depth with Emphasis on Thin Ice Clouds
J.C. Barnard, C.N. Long, E.I. Kassianov, S.A. McFarlane, J.M.
Comstock, M. Freer and G.M. McFarquhar Pp 46-55
An algorithm is presented here for determining cloud optical depth,
τ, using
data from shortwave broadband irradiances, focusing on the case
of optically thin clouds. This method is empirical and consists
of a one-line equation. This method is applied to cirrus clouds
observed at the Atmospheric Radiation Measurement Program Climate
Research Facility (ACRF) at Darwin, Australia, during the Tropical
Warm Pool International Cloud Experiment (TWP-ICE) campaign and
cirrus clouds observed at the ACRF Southern Great Plains (SGP) site.
These cases were chosen because independent verification of cloud
optical depth retrievals was possible. For the TWP-ICE case, the
calculated optical depths agree to within 1 unit with τ
calculated from a vertical profile of ice particle size distributions
obtained from an aircraft sounding. For the SGP case, the results
from the algorithm correspond reasonably well with τ
values obtained from an average over other retrieval methods, some
of which have been subject to independent verification. The medians
of the two time series are 0.79 and 0.81, for the empirical and
averaged values, respectively. Because such close agreement is likely
to be fortuitous and therefore not truly represent the performance
of our method, τ
values derived from our method were compared to values obtained
from lidar data. Over a three year period, the difference in median
values between the two methods is about 0.6, with the lidar optical
depths being larger. This tool may be applied wherever measurements
of the direct, diffuse, and total components of the shortwave broadband
flux are available at 1- to 5-minute resolution. Because these measurements
are made across the world, it then becomes possible to estimate
optical depth for both liquid water and ice clouds at many locations.
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