Cloud-top phase (CTP) impacts cloud albedo and pathways for ice particle nucleation, growth, and fallout within extratropical cyclones. This study uses airborne lidar, radar, and Rapid Refresh analysis data to characterize CTP within extratropical cyclones as a function of cloud-top temperature (CTT). During the 2020, 2022, and 2023 Investigation of Microphysics and Precipitation for Atlantic Coast-Threatening Snowstorms (IMPACTS) field campaign deployments, the Earth Resources 2 (ER-2) aircraft flew 26 research flights over the northeast and midwest United States to sample the cloud tops of a variety of extratropical cyclones. A training dataset was developed to create probabilistic phase classifications based on Cloud Physics Lidar measurements of known ice and liquid clouds. These classifications were then used to quantify dominant CTP in the top 150 m of clouds sampled by the Cloud Physics Lidar in storms during IMPACTS. Case studies are presented illustrating examples of supercooled liquid water at cloud top at different CTT ranges (238 , CTTs , 2358C) within extratropical cyclones. During IMPACTS, 19.2% of clouds had supercooled liquid water present at cloud top. Supercooled liquid was the dominant phase in extratropical cyclone cloud tops when CTTs were .2208C. Liquid-bearing cloud tops were found at CTTs as cold as 2378C.
SIGNIFICANCE STATEMENT: Identifying supercooled liquid cloud tops’ frequency is crucial for understanding
ice nucleation mechanisms at cloud top, cloud radiative effects, and aircraft icing. In this study, airborne lidar, radar,
and model temperature data from 26 research flights during the NASA IMPACTS campaign are used to characterize
extratropical cyclone cloud-top phase (CTP) as a function of cloud-top temperature (CTT). The results show that liquid
was the dominant CTP present in extratropical cyclone cloud tops when CTTs were .2208C with decreasing supercooled liquid cloud-top frequency at temperatures , 2208C. Nevertheless, liquid was present at CTTs as cold as 2378C.