Impacts of Representing Heterogeneous Distribution of Cloud Liquid and Ice on Phase Partitioning of Arctic Mixedâ€Phase Clouds with NCAR CAM5

In this study, we conduct sensitivity experiments with the Community Atmosphere Model version 5 to understand the impact of representing heterogeneous distribution between cloud liquid and ice on the phase partitioning in mixedâ€phase clouds through different perturbations on the Wegenerâ€Bergeronâ€...

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Bibliographic Details
Published in:Journal of Geophysical Research: Atmospheres
Main Authors: Zhang, Meng, Liu, Xiaohong, Diao, Minghui, D'Alessandro, John, Wang, Yong, Wu, Chenglai, Zhang, Damao, Wang, Zhien, Xie, Shaocheng
Format: Text
Language:unknown
Published: SJSU ScholarWorks 2019
Subjects:
atmospheric modeling
cloud microphysics
cloud water
environmental research
experiment
heterogeneity
model validation
phase transition
Meteorology
Oceanography and Atmospheric Sciences and Meteorology
Arctic
Online Access:https://scholarworks.sjsu.edu/faculty_rsca/4177
https://doi.org/10.1029/2019JD030502
Description
Summary:In this study, we conduct sensitivity experiments with the Community Atmosphere Model version 5 to understand the impact of representing heterogeneous distribution between cloud liquid and ice on the phase partitioning in mixedâ€phase clouds through different perturbations on the Wegenerâ€Bergeronâ€Findeisen (WBF) process. In two experiments, perturbation factors that are based on assumptions of pocket structure and the partial homogeneous cloud volume derived from the Highâ€performance Instrumented Airborne Platform for Environmental Research (HIAPER) Poleâ€toâ€Pole Observation (HIPPO) campaign are utilized. Alternately, a massâ€weighted assumption is used in the calculation of WBF process to mimic the appearance of unsaturated area in mixedâ€phase clouds as the result of heterogeneous distribution. Model experiments are tested in both single column and weather forecast modes and evaluated against data from the U.S. Department of Energy (DOE) Atmospheric Radiation Measurement (ARM) Program's Mixedâ€Phase Arctic Cloud Experiment (Mâ€PACE) field campaign and longâ€term groundâ€based multisensor measurements. Model results indicate that perturbations on the WBF process can significantly modify simulated microphysical properties of Arctic mixedâ€phase clouds. The improvement of simulated cloud water phase partitioning tends to be linearly proportional to the perturbation magnitude that is applied in the three different sensitivity experiments. Cloud macrophysical properties such as cloud fraction and frequency of occurrence of lowâ€level mixedâ€phase clouds are less sensitive to the perturbation magnitude than cloud microphysical properties. Moreover, this study indicates that heterogeneous distribution between cloud hydrometeors should be treated consistently for all cloud microphysical processes. The model vertical resolution is also important for liquid water maintenance in mixedâ€phase clouds.

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