A41H-0158
Long-Lifetime Ice Particles in Mixed-Phase Stratiform Clouds: Quasi-Steady and Recycled Growth

Thursday, 17 December 2015
Poster Hall (Moscone South)
Raymond A Shaw1, Fan Yang1 and Mikhail Ovchinnikov2, (1)Michigan Technological University, Houghton, MI, United States, (2)Pacific Northwest National Laboratory, Richland, WA, United States
Abstract:
Ice particles play an important role in precipitation and radiation transfer in stratiform mixed-phase clouds. Lagrangian ice particle tracking in mixed-phase clouds is applied in both a 3-D time dependent velocity field produced by a Large Eddy Simulation cloud model and in a 2-D idealized field. It is found that more than 10% of ice particles have lifetimes longer than 1.5 hours, much longer than the large eddy turnover time or the time for a crystal to fall through the depth of a non-turbulent cloud. An analysis of trajectories in a 2-D idealized field shows that there are two types of long lifetime ice particles: quasi-steady and recycled growth. For quasi-steady growth, ice particles are suspended in the updraft velocity region for a long time. For recycled growth, ice particles are trapped in the large-eddy structures, and whether ice particles grow or evaporate depends on the ice relative humidity profile within the boundary layer. Some ice particles can grow after each cycle in the trapping region, until they are too large to be trapped, and thus have long lifetimes. The relative contribution of the recycled ice particles to the cloud mean ice water content depends on both the dynamic and thermodynamic properties of the mixing layer. In particular, the total ice water content of a mixed phase cloud in a decoupled boundary layer can be much larger than that in a fully coupled boundary layer. This may help explain some of the observed variability of ice water content in mixed phase clouds with similar thermodynamic properties but different circulation structures.