Parameterization of the Extinction Coefficient in Ice and Mixed-Phase Arctic Clouds during the ISDAC Field Campaign
This report documents the history of attempts to directly measure cloud extinction, the current measurement device known as the Cloud Extinction Probe (CEP), specific problems with direct measurement of extinction coefficient, and the attempts made here to address these problems. Extinction coeffici...
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Pacific Northwest National Laboratory (U.S.)
2012
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| Online Access: | https://doi.org/10.2172/1035864 http://digital.library.unt.edu/ark:/67531/metadc833677/ |
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ftunivnotexas:info:ark/67531/metadc833677 2023-05-15T15:18:54+02:00 Parameterization of the Extinction Coefficient in Ice and Mixed-Phase Arctic Clouds during the ISDAC Field Campaign Korolev, A Shashkov, A Barker, H United States. Department of Energy. Office of Science. 2012-03-06 Text https://doi.org/10.2172/1035864 http://digital.library.unt.edu/ark:/67531/metadc833677/ English eng Pacific Northwest National Laboratory (U.S.) Atmospheric Radiation Measurement Program (U.S.) rep-no: DOE/SC-ARM-TR-105 grantno: DE-AC05-7601830 doi:10.2172/1035864 osti: 1035864 http://digital.library.unt.edu/ark:/67531/metadc833677/ ark: ark:/67531/metadc833677 Forecasting Climate Models Sensors Sampling Radiant Heat Transfer Aircraft Verification 54 Environmental Sciences Radiations Water Satellites Validation Simulation Weather Probes Clouds Report 2012 ftunivnotexas https://doi.org/10.2172/1035864 2016-08-13T22:11:35Z This report documents the history of attempts to directly measure cloud extinction, the current measurement device known as the Cloud Extinction Probe (CEP), specific problems with direct measurement of extinction coefficient, and the attempts made here to address these problems. Extinction coefficient is one of the fundamental microphysical parameters characterizing bulk properties of clouds. Knowledge of extinction coefficient is of crucial importance for radiative transfer calculations in weather prediction and climate models given that Earth's radiation budget (ERB) is modulated much by clouds. In order for a large-scale model to properly account for ERB and perturbations to it, it must ultimately be able to simulate cloud extinction coefficient well. In turn this requires adequate and simultaneous simulation of profiles of cloud water content and particle habit and size. Similarly, remote inference of cloud properties requires assumptions to be made about cloud phase and associated single-scattering properties, of which extinction coefficient is crucial. Hence, extinction coefficient plays an important role in both application and validation of methods for remote inference of cloud properties from data obtained from both satellite and surface sensors (e.g., Barker et al. 2008). While estimation of extinction coefficient within large-scale models is relatively straightforward for pure water droplets, thanks to Mie theory, mixed-phase and ice clouds still present problems. This is because of the myriad forms and sizes that crystals can achieve, each having their own unique extinction properties. For the foreseeable future, large-scale models will have to be content with diagnostic parametrization of crystal size and type. However, before they are able to provide satisfactory values needed for calculation of radiative transfer, they require the intermediate step of assigning single-scattering properties to particles. The most basic of these is extinction coefficient, yet it is rarely measured directly, and therefore verification of parametrizations is difficult. The obvious solution is to be able to measure microphysical properties and extinction at the same time and for the same volume. This is best done by in situ sampling by instruments mounted on either balloon or aircraft. The latter is the usual route and the one employed here. Yet the problem of actually measuring extinction coefficient directly for arbitrarily complicated particles still remains unsolved. Report Arctic University of North Texas: UNT Digital Library Arctic |
| institution |
Open Polar |
| collection |
University of North Texas: UNT Digital Library |
| op_collection_id |
ftunivnotexas |
| language |
English |
| topic |
Forecasting Climate Models Sensors Sampling Radiant Heat Transfer Aircraft Verification 54 Environmental Sciences Radiations Water Satellites Validation Simulation Weather Probes Clouds |
| spellingShingle |
Forecasting Climate Models Sensors Sampling Radiant Heat Transfer Aircraft Verification 54 Environmental Sciences Radiations Water Satellites Validation Simulation Weather Probes Clouds Korolev, A Shashkov, A Barker, H Parameterization of the Extinction Coefficient in Ice and Mixed-Phase Arctic Clouds during the ISDAC Field Campaign |
| topic_facet |
Forecasting Climate Models Sensors Sampling Radiant Heat Transfer Aircraft Verification 54 Environmental Sciences Radiations Water Satellites Validation Simulation Weather Probes Clouds |
| description |
This report documents the history of attempts to directly measure cloud extinction, the current measurement device known as the Cloud Extinction Probe (CEP), specific problems with direct measurement of extinction coefficient, and the attempts made here to address these problems. Extinction coefficient is one of the fundamental microphysical parameters characterizing bulk properties of clouds. Knowledge of extinction coefficient is of crucial importance for radiative transfer calculations in weather prediction and climate models given that Earth's radiation budget (ERB) is modulated much by clouds. In order for a large-scale model to properly account for ERB and perturbations to it, it must ultimately be able to simulate cloud extinction coefficient well. In turn this requires adequate and simultaneous simulation of profiles of cloud water content and particle habit and size. Similarly, remote inference of cloud properties requires assumptions to be made about cloud phase and associated single-scattering properties, of which extinction coefficient is crucial. Hence, extinction coefficient plays an important role in both application and validation of methods for remote inference of cloud properties from data obtained from both satellite and surface sensors (e.g., Barker et al. 2008). While estimation of extinction coefficient within large-scale models is relatively straightforward for pure water droplets, thanks to Mie theory, mixed-phase and ice clouds still present problems. This is because of the myriad forms and sizes that crystals can achieve, each having their own unique extinction properties. For the foreseeable future, large-scale models will have to be content with diagnostic parametrization of crystal size and type. However, before they are able to provide satisfactory values needed for calculation of radiative transfer, they require the intermediate step of assigning single-scattering properties to particles. The most basic of these is extinction coefficient, yet it is rarely measured directly, and therefore verification of parametrizations is difficult. The obvious solution is to be able to measure microphysical properties and extinction at the same time and for the same volume. This is best done by in situ sampling by instruments mounted on either balloon or aircraft. The latter is the usual route and the one employed here. Yet the problem of actually measuring extinction coefficient directly for arbitrarily complicated particles still remains unsolved. |
| author2 |
United States. Department of Energy. Office of Science. |
| format |
Report |
| author |
Korolev, A Shashkov, A Barker, H |
| author_facet |
Korolev, A Shashkov, A Barker, H |
| author_sort |
Korolev, A |
| title |
Parameterization of the Extinction Coefficient in Ice and Mixed-Phase Arctic Clouds during the ISDAC Field Campaign |
| title_short |
Parameterization of the Extinction Coefficient in Ice and Mixed-Phase Arctic Clouds during the ISDAC Field Campaign |
| title_full |
Parameterization of the Extinction Coefficient in Ice and Mixed-Phase Arctic Clouds during the ISDAC Field Campaign |
| title_fullStr |
Parameterization of the Extinction Coefficient in Ice and Mixed-Phase Arctic Clouds during the ISDAC Field Campaign |
| title_full_unstemmed |
Parameterization of the Extinction Coefficient in Ice and Mixed-Phase Arctic Clouds during the ISDAC Field Campaign |
| title_sort |
parameterization of the extinction coefficient in ice and mixed-phase arctic clouds during the isdac field campaign |
| publisher |
Pacific Northwest National Laboratory (U.S.) |
| publishDate |
2012 |
| url |
https://doi.org/10.2172/1035864 http://digital.library.unt.edu/ark:/67531/metadc833677/ |
| geographic |
Arctic |
| geographic_facet |
Arctic |
| genre |
Arctic |
| genre_facet |
Arctic |
| op_relation |
rep-no: DOE/SC-ARM-TR-105 grantno: DE-AC05-7601830 doi:10.2172/1035864 osti: 1035864 http://digital.library.unt.edu/ark:/67531/metadc833677/ ark: ark:/67531/metadc833677 |
| op_doi |
https://doi.org/10.2172/1035864 |
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1766349068163874816 |