Journal
ATMOSPHERIC CHEMISTRY AND PHYSICS
Volume 15, Issue 3, Pages 1503-1520Publisher
COPERNICUS GESELLSCHAFT MBH
DOI: 10.5194/acp-15-1503-2015
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Funding
- Office of Science of US Department of Energy as part of the Earth System Modeling Program
- National Natural Science Foundation of China [41205071]
- NCAR's Computational and Information Systems Laboratory
- DOE by Battelle Memorial Institute [DE-AC05-76RL01830]
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In order to improve the treatment of ice nucleation in a more realistic manner in the Community Atmosphere Model version 5.3 (CAM5.3), the effects of pre-existing ice crystals on ice nucleation in cirrus clouds are considered. In addition, by considering the in-cloud variability in ice saturation ratio, homogeneous nucleation takes place spatially only in a portion of the cirrus cloud rather than in the whole area of the cirrus cloud. Compared to observations, the ice number concentrations and the probability distributions of ice number concentration are both improved with the updated treatment. The pre-existing ice crystals significantly reduce ice number concentrations in cirrus clouds, especially at mid- to high latitudes in the upper troposphere (by a factor of similar to 10). Furthermore, the contribution of heterogeneous ice nucleation to cirrus ice crystal number increases considerably. Besides the default ice nucleation parameterization of Liu and Penner (2005, hereafter LP) in CAM5.3, two other ice nucleation parameterizations of Barahona and Nenes (2009, hereafter BN) and Karcher et al. (2006, hereafter KL) are implemented in CAM5.3 for the comparison. In-cloud ice crystal number concentration, percentage contribution from heterogeneous ice nucleation to total ice crystal number, and pre-existing ice effects simulated by the three ice nucleation parameterizations have similar patterns in the simulations with present-day aerosol emissions. However, the change (present-day minus pre-industrial times) in global annual mean column ice number concentration from the KL parameterization (3.24 x 10(6) m(-2)) is less than that from the LP (8.46 x 10(6) m(-2)) and BN (5.62 x 10(6) m(-2)) parameterizations. As a result, the experiment using the KL parameterization predicts a much smaller anthropogenic aerosol long-wave indirect forcing (0.24 W m(-2)) than that using the LP (0.46 W m(-2)) and BN (0.39W m(-2)) parameterizations.
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