Poster Session 2 |
| | Cloud Physics Poster Session II |
| | P2.1 | Numerical Simulations of Boundary Layer Marine Stratus: Diurnal Variability in Microphysics
Tomasz Sikora, DRI, Reno, NV; and S. K. Chai |
| | P2.2 | On activation of cloud condensation nuclei
Ruei-Fong Lin, UMBC/GEST Center, Greenbelt, MD; and D. O. Starr |
| | P2.3 | On the potential for overlapping cloud detection in high spectral resolution infrared data 
Shaima L. Nasiri, Univ. of Wisconsin, Madison, WI; and R. E. Holz, B. A. Baum, S. A. Ackerman, and P. Yang |
| | P2.4 | Investigation of a Visible Reflectance Parameterization for Determining Cloud Properties in Multi-layered Clouds
Robert F. Arduini, SAIC, Hampton, VA; and P. Minnis and D. F. Young |
| | P2.5 | Simulation of Arctic cloud properties during the spring season of SHEBA/FIRE-ACE experiment using a statistical cloud scheme in the CCCMA single-column model
Junhua Zhang, Dalhousie University, Halifax, NS, Canada; and U. Lohmann |
| | P2.6 | The Effect of Anthropogenic Pollution on Cloud Formation Within the ITCZ
Darrel Baumgardner, Universidad Nacional Autonoma de Mexico, Mexico City, D.F., Mexico; and G. B. Raga and J. C. Jimenez |
| | P2.7 | The effect of continental air Outbreaks on marine stratocumulus drizzle formation and cloud breakup
Lan Yi, CIMMS/Univ. of Oklahoma, Norman, OK; and Y. Kogan and D. Mechem |
| | P2.8 | Testing prognostic cloud parameterizations for convectively generated cirrus using cloud-resolving model simulations
Michael A. Zulauf, University of Utah, Salt Lake City, UT; and S. K. Krueger |
| | P2.9 | Impact of the cloud spatial distribution on solar UV radiation transfer
Didier Gillotay, Belgian Institute for Space Aeronomy, Brussels, Belgium; and T. Besnard and I. Labaye |
| | P2.10 | A One-Year Climatology Of Cloud Properties Derived From GOES-8 Over The Southeastern Pacific For PACS
J. Kirk Ayers, AS&M, Inc., Hampton, VA; and P. W. Heck, A. D. Rapp, P. Minnis, D. F. Young, W. L. Smith, and L. Nguyen |
| | P2.11 | An annual cycle of Arctic cloud microphysics
Matthew D. Shupe, NOAA/ETL, Boulder, CO; and T. Uttal and S. Y. Matrosov |
|  | P2.12 | Clustering of Cold Cloud Microphysical Properties
Charles C. Ryerson, U.S. Army Corps of Engineers Cold Regions Research and Engineering Lab., Hanover, NH; and R. A. Melloh and G. G. Koenig |
| | P2.13 | A cloud microphysics experiment over Northeast Brazil
Alexandre Araújo Costa, Universidade Estadual do Ceará, Fortaleza, Brazil; and C. J. de Oliveira, F. G. D. M. Pinheiro, G. P. Almeida, E. M. de Silva, M. S. Cunha, J. C. P. de Oliveira, L. A. T. Machado, R. L. Guedes, R. F. B. Teixeira, and D. F. Moncunill |
| | P2.14 | Diurnal cycle of liquid water path over the subtropical and tropical oceans
Robert Wood, University of Washington, Seattle, WA; and C. S. Bretherton and D. L. Hartmann |
| | P2.15 | Further analysis and improvements of ice crystal mass-size relationships
Brad Baker, SPEC, Inc., Boulder, CO; and C. Schmitt, P. Lawson, and D. Mitchell |
| | P2.16 | Ice initiation and evolution in large-eddy simulations using prognostic ice nuclei and CCN
Richard J. Cotton, UK Met Office, Farnborough, Hampshire, United Kingdom; and P. R. A. Brown |
| | P2.17 | Estimating the impact of natural and anthropogenic emissions on cloud chemistry: The influence of organic compounds
Lester Alfonso, Universidad Nacional Autonoma de Mexico, Mexico City, Mexico; and G. B. Raga |
| | P2.18 | The relation between the radar to lidar ratio and the effective radius of droplets in water clouds: an analysis of statistical models and observed drop size distributions (Formerly Poster P1.7)
Oleg A. Krasnov, Delft Univ. of Technology, Delft, Netherlands; and H. W. J. Russchenberg |