Small ice particles in tropospheric clouds: Fact or artifact? Airborne icing instrumentation evaluation experiment

The evidence for crystal bouncing and small ice article shattering is presented from wind tunnel studies and aircraft measurements using modified probe geometries. Direct experimental evidence for the shattering hypothesis is obtained with high-speed video recording led by the NASA Glenn Research Center, with support from Environment Canada (EC) at the Cox and Co. wind tunnel. The results show that contamination of particle size distribution caused by shattering of ice particles on probe tips and inlets is a significant problem for airborne microphysical characterization of ice clouds. Large ice particles are found to produce a higher level of contamination with their artifacts than small ice particles. The results also show that by modifying the probe inlets and by applying interarrival time algorithms, the effects of shattering can be significantly reduced.Peer reviewed: YesNRC publication: Ye

Toward ice formation closure in Arctic mixed-phase boundary layer clouds during ISDAC

A modeling study of a low-lying mixed-phase cloud layer observed on 8 April 2008 during the Indirect and Semi-Direct Aerosol Campaign is presented. Large-eddy simulations with size-resolved microphysics were used to test the hypothesis that heterogeneous ice nucleus (IN) concentrations measured above cloud top can account for observed ice concentrations, while also matching ice size distributions, radar reflectivities, and mean Doppler velocities. The conditions for the case are favorable for the hypothesis: springtime IN concentrations are high in the Arctic, the predominant ice habit falls slowly, and overlying IN concentrations were greater than ice particle number concentrations. Based on particle imagery, we considered two dendrite types, broad armed (high density) and stellar (low density), in addition to high and low density aggregates. Two simulations with low-density aggregates reproduced observations best overall: one in which IN concentrations aloft were increased fourfold (as could have been present above water saturation) and another in which initial IN concentrations were vertically uniform. A key aspect of the latter was an IN reservoir under the well-mixed cloud layer: as the simulations progressed, the reservoir IN slowly mixed upward, helping to maintain ice concentrations close to those observed. Given the uncertainties of the measurements and parameterizations of the microphysical processes embedded in the model, we found agreement between simulated and measured ice number concentrations in most of the simulations, in contrast with previous modeling studies of Arctic mixed-phase clouds, which typically show a large discrepancy when IN are treated prognostically and constrained by measurements. Copyright 2011 by the American Geophysical Union.Peer reviewed: YesNRC publication: Ye