Laserfiche WebLink
<br />1 - <br /> <br /> <br />....... <br /> <br />.,,) <br /> <br />.- <br /> <br />. <br /> <br />I. <br /> <br />. <br /> <br />. <br /> <br />Ie <br />I <br /> <br />be made of the rate of condensation of water substance <br /> <br />and of the time available for particle growth. <br /> <br />Experiment 3: Spatial and temporal distribution of supercooled liquid <br /> <br />water. The spatial and temporal distribution of super- <br /> <br />cooled liquid w;ater in the vicinity of the radiometer <br /> <br />will be described and related to the underlying <br /> <br />topography. The temperature of the liquid water will be <br /> <br />derived from Iidar measurements of the. height of the <br /> <br />liquid water. The radiometer and Iidar measurements of <br /> <br />supercooled liquid water will be related to surface <br /> <br />measurements. <br /> <br />Experiment 4: Refinement of radiometer and Ka-band radar data. An <br /> <br />attempt will be made to add range information to the <br /> <br />radiometer liquid water data set in order to gain detail <br /> <br />as to the physkal location of liquid water. An attempt <br /> <br />will be made toO interpret the Ka-band radar circular <br /> <br />depolarization ratio using the lidar linear depolariza- <br /> <br />tion ratio. <br /> <br />Experiment 5: Hydrometeor trajectories. Trajectories taken by hydrome- <br /> <br />teors as they grow from cloud to precipitation sizes will <br /> <br />be described. <br /> <br />Experiment 6: Precipitation pr1ocesses. An assessment will be made of <br /> <br />the likely microphysical processes responsible for preci- <br /> <br />pitation particll~ growth and the rates of these pro- <br /> <br />cesses. <br /> <br />Experiment 7: Relation of liquid water and precipitation particle <br /> <br />growth. <br /> <br />The physical interdependence of precipitation <br /> <br />7 <br />