Poster Session 1 | |||
Cloud Physics Poster Session I | |||
P1.1 | A system for the impaction and automated optical sizing of giant aerosol particles Jorgen B. Jensen, NCAR, Boulder, CO; and S. Beaton, J. Stith, D. C. Rogers, and M. Colon | ||
P1.2 | The Significance of Giant Aerosol in Continental Cloud Ashley L. Shackelford Jr., Purdue University, West Lafayette, IN; and S. Lasher-Trapp and J. Hudson | ||
P1.3 | Bulk parameterization of giant CCN David B. Mechem, CIMMS/Univ. of Oklahoma, Norman, OK; and Y. L. Kogan | ||
Poster P1.4 has been moved. New Paper number 1.4A | |||
P1.5 | Water uptake of soot particles emitted from a Jing-CAST soot generator Eszter Barthazy, ETH, Zurich, Switzerland; and O. Stetzer, C. Derungs, H. Saathoff, and U. Lohmann | ||
P1.6 | Concerning the nucleation of ice by organics Eli Ochshorn, Michigan Technological University, Houghton, MI; and C. Robinson, G. Wicks, and W. Cantrell | ||
P1.7 | Investigation of atmospheric aerosol with multiwavelength lidar G. Karasiñski, Institute of Experimental Physics, Warsaw University, Warsaw, Poland; and T. Stacewicz, S. Chudzynski, W. Skubiszak, S. Malinowski, and A. Jagodnicka | ||
P1.8 | Analysis of insoluble particles contained in single cloud droplets and ice crystals Corinna Hoose, ETH, Zurich, Switzerland; and E. Barthazy and U. Lohmann | ||
P1.9 | The effect of cloud top entrainment on the aerosol indirect effect R. M. Sheppard, ETH, Zurich, Switzerland; and U. Lohmann | ||
P1.10 | A model for ice nucleation in the AIDA cloud simulation chamber. Part 1: Observations and model description, using key measurements to constrain the model R. J. Cotton, UK Met Office, Exeter, Devon, United Kingdom; and P. R. Field and O. Moehler | ||
P1.11 | Similarities and contrasts in observed aerosol and cloud microphysical characteristics in India and the Arabian Peninsula: the effect on coalescence processes Roelof Bruintjes, NCAR, Boulder, CO; and V. Salazar, T. Semeniuk, D. Breed, T. Jensen, S. Piketh, P. Buseck, and A. Al Mandoos | ||
P1.12 | A case study of aerosol-cloud-radiation interaction Hung-Neng Steve Chin, LLNL, Livermore, CA; and C. C. Chuang | ||
P1.13 | A study of vertical liquid water profiles of clouds from in-situ measurements Alexei V. Korolev, Environment Canada, Downsview, ON, Canada; and G. A. Isaac, J. W. Strapp, and S. G. Cober | ||
P1.14 | Small cloud particle shape and its phase determination in mixed-phase clouds Gong Zhang, Univ. of Illinois, Urbana, IL; and G. M. McFarquhar | ||
P1.15 | Observational constraints on cloud thermodynamic phase in midlatitude storms Catherine M. Naud, Columbia University, New York, NY; and A. Del Genio | ||
P1.16 | LES microphysical study of interactions between cloud dynamics and drizzle Yefim L. Kogan, CIMMS/Univ. of Oklahoma, Norman, OK | ||
P1.17 | Sensitivity of the retrieval of stratocumulus cloud liquid water and precipitation flux to Doppler radar parameters Yefim L. Kogan, CIMMS/Univ. of Oklahoma, Norman, OK; and Z. N. Kogan and D. B. Mechem | ||
P1.18 | The radar discrepancy: why do cloud radars measure less stratocumulus reflection than expected? Herman Russchenberg, Delft University of Technology, Delft, Netherlands; and O. Krasnov | ||
P1.19 | Retrieval of Cloud Liquid Water Content Profiles with Radar and Lidar: Application to Multi-annual Data Sets and Comparison with Microphysical Cloud Simulations Oleg Krasnov, Delft University of Technology, Delft, Netherlands; and H. Russchenberg, A. Khain, and M. Pinsky | ||
P1.20 | Retrieval of cloud droplet concentration of liquid-water clouds from ground based remote sensing observation Ela Grzeszczak, Warsaw University, Warsaw, Poland; and H. Pawlowska, R. Boers, and H. K. Baltink | ||
P1.21 | Raman lidar measurements for the characterization of aerosol and cloud microphysical properties Paolo Di Girolamo, University of Basilicata, Potenza, Italy; and D. Summa and D. Sabatino | ||
P1.22 | Observations of Stratiform Rain by cm- and mm- Wavelength Radars Lin Tian, University of Maryland, Baltimore County, Greenbelt, MD; and G. Heymsfield, L. Li, and X. Li | ||
Poster P1.23 has been removed | |||
P1.24 | Scale dependence of variability in continental stratiform clouds Zena N. Kogan, CIMMS/Univ. of Oklahoma, Norman, OK; and Y. L. Kogan and D. B. Mechem | ||
P1.25 | A common microphysical structure for midlevel mixed phase clouds in the mid-latitudes: Results from the Cloud Layer Experiment (CLEX-9) Jianguo Niu, Texas A&M Univ., College Station, TX; and L. D. Carey, P. Yang, J. A. Kankiewicz, and T. H. Vonder Haar | ||
P1.26 | Radiative Influences on the Glaciation Time-Scales of Mixed-Phase Clouds Zach Lebo, Penn State Univ., University Park, PA; and N. Johnson and J. Y. Harrington | ||
P1.27 | Drizzle-induced Change in the Organization of Stratocumulus Verica Savic-Jovcic, Univ. of California, Los Angeles, CA; and B. Stevens | ||
P1.28 | New Parcel Model with Detailed Cloud Microphysics Akihiro Hashimoto, Advanced Earth Science and Technology Organization, Tsukuba, Japan; and M. Murakami, N. Kuba, R. Misumi, N. Orikasa, K. I. Maruyama, A. Saito, and J. P. Chen | ||
P1.29 | Influence of SST, surface stability and radiation on coastal stratus Tracy Haack, NRL, Monterey, CA; and S. D. Burk | ||
P1.30 | Development of convectively mixed layer and formation in it observed-- by an instrumented aircraft Masataka Murakami, MRI, Tsukuba, Ibaraki, Japan; and N. Orikasa, H. Horie, H. Kuroiwa, and H. Minda | ||
P1.31 | Fine-scale horizontal structure of Arctic mixed-phase clouds Mahlon Rambukkange, Penn State Univ., University Park, PA; and J. Verlinde, E. Eloranta, E. Luke, P. Kollias, and M. Shupe | ||
P1.32 | Observations and cloud-resolving simulations of Arctic stratus Gijs De Boer, Univ. of Wisconsin, Madison, WI; and G. J. Tripoli, E. W. Eloranta, and T. Hashino | ||
P1.33 | The relationship between observed Arctic cloud vertical structure and the recent sea ice thinning Paquita Zuidema, Univ. of Miami/RSMAS, Miami, FL | ||
P1.34 | Study the seasonal and interannual variations of mixed-phase cloud properties based on the observations from the ARM Northern Slope Alaska site Zhien Wang, University of Wyoming, Laramie, WY | ||
P1.35 | Effects of turbulent structure of the boundary layer on the formation of drizzle from warm stratiform clouds Leehi Magaritz, The Hebrew University of Jerusalem, Jerusalem, Israel; and N. Benmoshe, M. Pinsky, A. P. Khain, and A. Sterkin | ||
P1.36 | Drizzle formation in marine stratocumulus clouds—experimental and modeling studies Piotr Rasinski, Warsaw University, Warsaw, Poland; and H. Pawlowska and W. W. Grabowski | ||
P1.37 | Entrainment and mixing in a high-resolution large-eddy simulation of stratocumulus Steven K. Krueger, University of Utah, Salt Lake City, UT; and M. A. Zulauf and P. Bogenschutz | ||
P1.38 | A strategy for improvement of LES prediction of stratocumulus entrainment using the 'one-dimensional turbulence' simulation method Alan R. Kerstein, Sandia National Laboratories, Livermore, CA; and S. Wunsch and S. K. Krueger | ||
P1.39 | Comparison of LWC measurements on the NCAR C-130 in AIRS-2 David C. Rogers, NCAR, Broomfield, CO; and J. Hallett, A. Schanot, C. Twohy, J. Jensen, J. Stith, and G. Vidaurre | ||
P1.40 | Comparison of large-eddy simulations with a single-column model: Implications for mid-level cloud parameterization Adam J. Smith, Univ. of Wisconsin, Milwaukee, WI; and B. M. Griffin, J. C. Golaz, and V. E. Larson | ||
P1.41 | Cloud observations from ICESat, and comparison with ECMWF model-generated clouds Maike Ahlgrimm, Colorado State University, Fort Collins, CO | ||
P1.42 | Analysis of microphysical data in an orographic environment to evaluate a polarization radar-based hydrometeor typing algorithm David M. Plummer, Univ. of Illinois, Urbana, IL; and S. Goeke | ||
P1.43 | 28,000 nmi of microphysical measurements in supercooled clouds Richard K. Jeck, FAA Technical Center, Atlantic City, NJ | ||
P1.44 | Tropical and Midlatiatude Cirrus Cloud Properties and Model Applications Min Deng, Univ. of Utah, Salt Lake City, UT; and G. G. Mace | ||
P1.45 | Space-based thin cirrus cloud observations of the future D. E. Flittner, NASA/LaRC, Hampton, VA; and E. J. Llewellyn, A. E. Bourassa, and D. A. Degenstein | ||
P1.46 | Retrieval of ice cloud properties using hyperspectral infrared channel observations Yong-Keun Lee, Texas A&M University, College Station, TX; and P. Yang, H. -. L. Huang, B. A. Baum, and Y. Hu | ||
P1.47 | Microphysical proporties of subvisible cirrus R. Paul Lawson, SPEC Inc, Boulder, CO; and B. Pilson, B. Baker, and Q. Mo | ||
P1.48 | Cirrus anvil dissipation simulated by a mesoscale model with bulk microphysics R.-F. Lin, NASA/GEST, Univ. of Maryland, Baltimore County and NASA/GSFC, Greenbelt, MD; and D. O. Starr, A. Lare, T. M. Rickenbach, and B. Demoz | ||
P1.49 | Increase of cloud droplet size with aerosol optical depth: a likely new effect of aerosols on climate Tianle Yuan, Univ. of Maryland, College Park, MD; and Z. Li, F. L. Chang, B. Vant-Hull, and D. Rosenfeld | ||
P1.50 | Remote sensing of small ice crystal concentrations in relation to FSSP measurements David L. Mitchell, DRI, Reno, NV; and D. H. DeSlover and R. P. D'Entremont | ||
P1.51 | Plausibility of in situ Measurements of Numerous Small Crystals in Anvil Cirrus Clouds Eric Jensen, NASA/ARC, Moffett Field, CA; and D. Baumgardner, G. Kok, and G. McFarquhar | ||
P1.52 | Radar scattering by realistic ice aggregates Christopher David Westbrook, Univ. of Reading, Reading, United Kingdom; and R. J. Hogan | ||
P1.53 | Characteristics of cirrus crystal shapes from hydrometeor videosonde data Narihiro Orikasa, MRI, Tsukuba, Ibaraki, Japan; and M. Murakami | ||
P1.54 | Cirrus observations during MPACE Daniel H. DeSlover, CIMSS/Univ. of Wisconsin, Madison, WI; and R. Holz, D. Turner, and H. Revercomb | ||
P1.55 | Theory and observations of ice particle evolution using Doppler radar Christopher David Westbrook, Univ. of Reading, Reading, United Kingdom; and R. J. Hogan | ||
P1.56 | Diffusion growth of solid and hollow hexagonal ice columns Chiou-Jiu Chen, Univ. of Wisconsin, Madison, WI; and P. K. Wang | ||
P1.57 | Numerical Simulation of Mammatus-Like Clouds in Cirrus Outflow Anvils Katharine M. Kanak, CIMMS/Univ. of Oklahoma, Norman, OK; and J. M. Straka and D. M. Schultz | ||
Poster P1.58 has been moved. New Poster number is P2.67 | |||
P1.59 | Measured Ice Crystal Capacitances: the Failure of the Electrostatic Analogy Matthew P. Bailey, DRI, Reno, NV; and J. Hallett | ||
P1.60 | Importance of a proper treatment of ice crystal sedimentation for cirrus clouds in large-scale models Peter Spichtinger, ETH, Zurich, Switzerland; and K. Gierens and U. Lohmann | ||
P1.61 | Impact of the mass-accomodation coefficient on cirrus Robert W. Carver, Penn State Univ., University Park, PA; and J. Y. Harrington | ||
P1.62 | Doppler radar investigation into the representation of evaporating ice in operational models Jonathan M. Wilkinson, Univ. of Reading, Reading, Berks., United Kingdom; and R. J. Hogan and A. J. Illingworth | ||
P1.63 | Influence of Nucleating Aerosols on Tropical Cyclone Initiation and Development Henian Zhang, University of Illinois, Urbana, IL; and G. M. McFarquhar, S. M. Saleeby, and W. R. Cotton | ||
P1.64 | Comparison of bulk and bin warm rain microhpysics models using a kinematic framework Hugh Morrison, NCAR, Boulder, CO; and W. W. Grabowski | ||
P1.65 | High-resolution mesoscale simulations on the role of shallow and deep convection on dust emission and transport in a desert area Tetsuya Takemi, Tokyo Institute of Technology, Yokohama, Japan |
Monday, 10 July 2006: 5:00 PM-7:00 PM, Grand Terrace
* - Indicates paper has been withdrawn from meeting