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Observing Ice in Clouds from SpaceThere are many satellite observations of cloud top properties and the liquid and rain content of clouds, however, we do not yet quantitatively understand the processes that control the water budget of the upper troposphere where ice is the predominant phase, and how these processes are linked to precipitation processes and the radiative energy budget. The ice in clouds in the upper troposphere either melts into rain or is detrained, and persists, as cirrus clouds affecting the hydrological and energy cycle, respectively. Fully modeling the Earth's climate and improving weather and climate forecasts requires accurate satellite measurements of various cloud properties at the temporal and spatial scales of cloud processes. These properties include cloud horizontal and vertical structure, cloud water content and some measure of particle sizes and shapes. The uncertainty in knowledge of these ice characteristics is reflected in the large discrepancies in model simulations of the upper tropospheric water budget. Model simulations are sensitive to the partition of ice between precipitation and outflow processes, i.e., to the parameterization of ice clouds and ice processes. One barrier to achieving accurate global ice cloud properties is the lack of adequate observations at millimeter and submillimeter wavelengths (183-874 GHz). Recent advances in instrumentation have allowed for the development and implementation of an airborne submillimeter-wave radiometer. The brightness temperatures at these frequencies are especially sensitive to cirrus ice particle sizes (because they are comparable to the wavelength). This allows for more accurate ice water path estimates when multiple channels are used to probe into the cloud layers. Further, submillimeter wavelengths offer simplicity in the retrieval algorithms because they do not probe into the liquid and near surface portions of clouds, thus requiring only one term of the radiative transfer equation (ice scattering) to relate brightness temperatures to ice. The next step is a satellite mission designed to acquire global Earth radiance measurements in the submillimeter-wave region, thus bridging the measurement gap between microwave sounders and shorter-wavelength infrared and visible sensors. This presentation provides scientific justification and an approach to measuring ice water path and particle size from a satellite platform that spans a range encompassing both the hydrologically active and radiatively active components of cloud systems.
Document ID
20080045463
Acquisition Source
Goddard Space Flight Center
Document Type
Conference Paper
Authors
Ackerman, S.
(Wisconsin Univ. Madison, WI, United States)
Star, D. O'C.
(NASA Goddard Space Flight Center Greenbelt, MD, United States)
Skofronick-Jackson, G.
(NASA Goddard Space Flight Center Greenbelt, MD, United States)
Evans, F.
(Colorado Univ. Boulder, CO, United States)
Wang, J. R.
(NASA Goddard Space Flight Center Greenbelt, MD, United States)
Norris, P.
(NASA Goddard Space Flight Center Greenbelt, MD, United States)
daSilva, A.
(NASA Goddard Space Flight Center Greenbelt, MD, United States)
Soden, B.
(Miami Univ. FL, United States)
Date Acquired
August 24, 2013
Publication Date
February 24, 2006
Subject Category
Meteorology And Climatology
Meeting Information
Meeting: MICRORAD 06
Location: San Juan
Country: Puerto Rico
Start Date: February 24, 2006
End Date: March 3, 2006
Distribution Limits
Public
Copyright
Other

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