TY - JOUR
T1 - Dependence of Ice Microphysical Properties on Environmental Parameters
T2 - Results from HAIC-HIWC Cayenne Field Campaign
AU - Hu, Yachao
AU - McFarquhar, Greg M.
AU - Wu, Wei
AU - Huang, Yongjie
AU - Schwarzenboeck, Alfons
AU - Protat, Alain
AU - Korolev, Alexei
AU - Rauber, Robert M.
AU - Wang, Hongqing
N1 - Publisher Copyright:
© 2021 American Meteorological Society.
PY - 2021/9
Y1 - 2021/9
N2 - High ice water content (HIWC) regions above tropical mesoscale convective systems are investigated using data from the second collaboration of the High Altitude Ice Crystals and High Ice Water Content projects (HAIC-HIWC) based in Cayenne, French Guiana, in 2015. Observations from in situ cloud probes on the French Falcon 20 determine the microphysical and thermodynamic properties of such regions. Data from a 2D stereo probe and precipitation imaging probe show how statistical distributions of ice crystal mass median diameter (MMD), ice water content (IWC), and total number concentration (Nt) for particles with maximum dimension (Dmax) . 55 mm vary with environmental conditions, temperature (T), and convective properties such as vertical velocity (w), MCS age, distance away from convective peak (L), and surface characteristics. IWC is significantly correlated with w, whereas MMD decreases and Nt increases with decreasing T consistent with aggregation, sedimentation, and vapor deposition processes at lower altitudes. MMD typically increases with IWC when IWC, 0.5 g m23, but decreases with IWC when IWC . 0.5 g m23 for 2158 # T # 258C. Trends also depend on environmental conditions, such as the presence of convective updrafts that are the ice crystal source, MMD being larger in older MCSs consistent with aggregation and less injection of small crystals into anvils, and IWCs decrease with increasing L at lower T. The relationship between IWC and MMD depends on environmental conditions, with correlations decreasing with decreasing T. The strength of correlation between IWC and Nt increases as T decreases.
AB - High ice water content (HIWC) regions above tropical mesoscale convective systems are investigated using data from the second collaboration of the High Altitude Ice Crystals and High Ice Water Content projects (HAIC-HIWC) based in Cayenne, French Guiana, in 2015. Observations from in situ cloud probes on the French Falcon 20 determine the microphysical and thermodynamic properties of such regions. Data from a 2D stereo probe and precipitation imaging probe show how statistical distributions of ice crystal mass median diameter (MMD), ice water content (IWC), and total number concentration (Nt) for particles with maximum dimension (Dmax) . 55 mm vary with environmental conditions, temperature (T), and convective properties such as vertical velocity (w), MCS age, distance away from convective peak (L), and surface characteristics. IWC is significantly correlated with w, whereas MMD decreases and Nt increases with decreasing T consistent with aggregation, sedimentation, and vapor deposition processes at lower altitudes. MMD typically increases with IWC when IWC, 0.5 g m23, but decreases with IWC when IWC . 0.5 g m23 for 2158 # T # 258C. Trends also depend on environmental conditions, such as the presence of convective updrafts that are the ice crystal source, MMD being larger in older MCSs consistent with aggregation and less injection of small crystals into anvils, and IWCs decrease with increasing L at lower T. The relationship between IWC and MMD depends on environmental conditions, with correlations decreasing with decreasing T. The strength of correlation between IWC and Nt increases as T decreases.
KW - Cloud microphysics
KW - Convective storms
KW - Ice crystals
KW - Ice particles
KW - Tropics
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U2 - 10.1175/JAS-D-21-0015.1
DO - 10.1175/JAS-D-21-0015.1
M3 - Article
AN - SCOPUS:85125584214
SN - 0022-4928
VL - 78
SP - 2957
EP - 2981
JO - Journal of the Atmospheric Sciences
JF - Journal of the Atmospheric Sciences
IS - 9
ER -