利用NCEP再分析资料、 TRMM卫星资料和WRF数值预报模式, 对2008年1月12日-2月2日湖南冻雨的成因进行了研究。结果表明, 冻结层和融化层之间的水汽辐合和较强的上升运动是冻雨产生的两个必要条件。湖南南部强冻雨的产生需要强水汽辐合和上升运动, 相对较厚的融化层和高的暖中心温度。卫星云图上在融化层能够观测到亮带, 回波强度较大; 弱冻雨期间云顶亮温相对较高, 观测不到亮带, 融化层厚度薄。当考虑真实地形影响时, 冻结层在雪峰山脉的北面存在加厚过程, 冷中心温度明显偏低; 受高大山脉影响, 融化层的水汽加强, 厚度和强度比加入虚拟地形影响时偏厚偏强, 中上层对流不稳定增大, 上升运动明显加强; 当加入虚拟地形因素影响时, 上升运动减小。
Using NCEP reanalysis data, TRMM satellite data, the formation mechanism of freezing rain in Hunan from 12 January to 2 February 2008 was studied through terrain sensitive experiment of WRF numerical forecasting model. The results show that the water vapor convergence and the strong upward movement between the freezing layer and the melting layer are the essential conditions for the formation of freezing rain. The strong water vapor convergenc and upward movement and relatively thick melting layer with high temperature in the center are important to the appearance of strong freezing rain in Southern Hunan. During the strong freezing rain period, bright band in the melting layer can be seen from the satellite image and radar echo intensity is strong. Meanwhile, the relatively high cloud top brightness temperature, no bright band on satellite image and thin melting layer are the features of the weak sleet period. When the influence of actual terrain considered, there is a thickening progress of the frozen layer in the north of Xuefeng mountain area with a obviously low temperature in the cold center. Under the influence of big mountains, water vapor in the melting layer increases, the connective instability in the upper level of melting layer increases, the upward movement enhances and the thickness and strength of melting layer are thicker and stronger than that impacted by the virtual terrain.
[1]陶诗言, 卫捷. 2008年1月我国南方严重冰雪灾害过程分析[J].气候与环境研究, 2008, 13(4): 337-350.
[2]王东海, 柳崇建, 刘英, 等. 2008年1月中国南方低温雨雪冻雨天气特征及其天气动力学成因的初步分析[J].气象学报, 2008, 66(3): 405-423.
[3]杨贵名, 孔期, 毛冬艳, 等. 2008年初“低温雨雪冻雨”灾害天气的持续性原因分析[J].气象学报, 2008, 66(5): 836-849.
[4]辜旭赞. 2008年1月我国南方持续雨雪过程的诊断分析[J]. 高原气象, 2011, 30(1): 150-157.
[5]叶成志, 吴贤云, 黄小玉. 湖南省历史罕见的一次低温雨雪冻雨灾害天气分析[J].气象学报, 2009, 67(3): 488-500.
[6]马宁,李跃凤,琚建华. 2008年初中国南方低温雨雪冰冻天气的季节内振荡特征[J]. 高原气象, 2011, 30(2): 318-327.
[7]李艳, 王式功, 金荣花, 等. 我国南方低温雨雪冰冻灾害期间阻塞高压异常特征分析[J]. 高原气象, 2012, 31(1): 94-101.
[8]丁一汇, 王遵娅, 宋亚芳, 等.中国南方2008年1月罕见低温雨雪冻雨灾害发生的原因及其与气候变暖的关系[J].气象学报, 2008, 66(5): 808-825.
[9]黎惠金, 李江南, 林文实, 等. 2008年初南方冻雨云物理过程的模拟研究[J].高原气象, 2011, 30(4): 942-950.
[10]高洋, 吴统文, 陈葆德. 2008年1月我国南方冻雨过程的热力异常及其形成原因[J].高原气象, 2011, 30(5): 1526-1533.
[11]赵思雄, 孙建华. 2008年初南方雨雪冻雨天气的环流场与多尺度特征[J].气候与环境研究, 2008, 13(4): 351-367.
[12]孙建华, 赵思雄. 2008年初南方雨雪冻雨灾害天气的大气层结和地面特征的数值模拟[J].气候与环境研究, 2008, 13(4): 510-519.
[13]易明建, 陈月娟, 周任君, 等. 2008年中国南方雪灾与平流层极涡异常的等熵位涡分析[J].高原气象, 2009, 28(4): 880-888.
[14]李登文,乔琪,魏涛. 2008年初我国南方冻雨雪天气环流及垂直结构分析[J].高原气象, 2009, 28(5): 1140-1148.
[15]严小冬,吴战平,古书鸿. 贵州冻雨时空分布变化特征及其影响因素浅析[J].高原气象, 2009, 28(3): 694-701.
[16]曾明剑, 陆维松, 梁信忠, 等. 地形对2008年中国南方持续性冻雨灾害分布影响的数值模拟[J].高原气象, 2009, 28(6): 1376-1387.
[17]徐辉, 金荣花. 地形对2008年初湖南雨雪冻雨天气的影响分析[J].高原气象, 2010, 29(4): 957-967.
[18]Renato. Sensitivity of ice storms in the southeastern united states to atlantic SST-insights from a case study of the December 2002 storm[J]. Mon Wea Rev, 2006, 134: 1454-1464.
[19]John C. A climatology of freezing rain in the Great Lakes Region of North Americ[J]. Mon Wea Rev, 2000, 128: 3574-3588.
[20]Robert T M R. The relative importance of warm rain and melting processes in freezing precipitation events [J]. J Appl Meteor, 2000, 39: 1185-1195.
[21]Ben C B.Regional and local influences on freezing drizzle, freezing rain, and ice pellet events[J]. Wea forecasting, 2000, 15: 485-508.
[22]傅云飞, 刘栋, 王雨, 等.热带测雨卫星综合探测结果之“云娜”台风降水云与非降水云特征[J]. 气象学报, 2007, 65(3): 10-22.
[23]Wallace J M, Hobbs P V. Atmospheric Science: An Introductory Survey[J]. Academic Press, 1977: 467.
[24]Iguchi T, Meneghini R. Intercomparison of single-frequency methods for retrieving a vertical rain profile from airborne or spaceborne radar date[J]. J Atmos Oceanic Technol, 1994, 11: 1507-1516.
[25]Awaka J, Iguchi T, Okamto K. Early results on rain type classification by the Tropical Rainfall Measuring Missino(TRMM) Precipitation radar[C]. Pro.8th URSI Commission F Open Symp.1998, Averior, Portugal, 134-146.
[26]Kummerow C, Barnes W, Kozu T, et al. The tropical rainfall measuring mission(TRMM) sensor package[J]. J Atmos Ocean Technol, 1998, 15: 809-817.
[27]Chuntao Liu, Edward J, Cecil D J, et al. A cloud and precipitation feature database from nine years of TRMM observations[J]. JAppl Meteor Clima, 2008, 47: 2712-2728.
[28]廖玉芳, 潘志祥, 吴贤云, 等. 湖南雨凇[M]. 北京: 气象出版社, 2011, 7 ISBN 978-7-5029-5230-3.
