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气象:2016,42(11):1351-1363
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1951—2015年乌鲁木齐市降温过程频数及强度气候特征
(1.中国气象局乌鲁木齐沙漠气象研究所,乌鲁木齐 830002 中亚大气科学研究中心,乌鲁木齐 830002;2.中亚大气科学研究中心,乌鲁木齐 830002 新疆气候中心,乌鲁木齐 830002)
Climate Characteristics of Frequency and Intensity of Cooling Process in Urumqi During 1951-2015
(1.Institute of Desert Meteorology, CMA, Urumqi 830002 Center of Central Asia Atmospheric Science Research, Urumqi 830002;2.Center of Central Asia Atmospheric Science Research, Urumqi 830002 Xinjiang Climate Center, Urumqi 830002)
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投稿时间:2015-12-18    修订日期:2016-06-26
中文摘要: 利用乌鲁木齐市气象站1951年1月1日至2015年12月31日的逐日气温资料,以日最低气温及其降温幅度为指标,整理出乌鲁木齐市近65年降温过程数据库,将降温过程分为Ⅰ级(弱)、Ⅱ级(中等强度)、Ⅲ级(较强)、Ⅳ级(强)以及Ⅴ级(寒潮)5个等级,分析了乌鲁木齐市各级降温过程的频数、持续日数、过程不同时段降温幅度、过程最低气温、过程最低气温距平偏低幅度等要素气候特征。结果如下:(1)1951—2015年,乌鲁木齐市出现降温过程5834次,平均每年89.8次,其中Ⅰ级(弱)降温过程占78.1%。降温过程的频数季节分布较均匀,但Ⅳ级(强)和Ⅴ级(寒潮)降温过程在春季最多。在降温过程异常偏多与偏少年之间,6—8月的过程频数差异最大,4和9月过程频数差异较小。年平均降温过程频数在7个年代际中差异不大;随年代际增长,Ⅰ级(弱)降温过程频数在增加,Ⅴ级(寒潮)降温过程频数却在减少。(2)1951—2015年,乌鲁木齐市5834次降温过程的持续日数平均为1.89 d,其中持续1 d的过程占49.0%。随降温过程等级由Ⅰ级到Ⅴ级提高,过程持续日数最高出现频率也从1 d过渡到3 d。Ⅳ级(强)和Ⅴ级(寒潮)降温过程均表现为秋末到冬季各月的持续日数长,春季各月短。(3)65年来,乌鲁木齐市过程降温幅度平均为-4.4℃,秋季降温幅度最强,夏季最弱。Ⅳ级(强)以及Ⅴ级(寒潮)过程的降温幅度最强的月份分别是6和12月。65年来,乌鲁木齐市降温过程的最大24、48和72 h降温幅度平均值分别为-3.1、-5.5和-7.4℃,最大24 h降温幅度是春季最强,冬季最弱;48 h降温幅度是春季最强,夏季最弱;72 h降温幅度是冬季最强,夏季最弱。(4)1951—2015年,乌鲁木齐市降温过程的最低气温平均值为0.3℃,冬季各月最低,夏季各月最高,带有显著的季节背景特征。过程最大日气温距平的平均值为-1.9 ℃,随降温过程等级由Ⅰ级到Ⅴ级提高,距平偏低幅度依次增强,Ⅴ级(寒潮)降温过程平均达到-8.5℃。(5)在乌鲁木齐市降温过程频数异常偏多月份,对应在500 hPa高空新疆主要受纬向西风气流控制,较稳定的西风气流上多短波槽脊东移影响新疆;在降温过程频数异常偏少月份,在500 hPa高空新疆主要受西北气流控制,处于高纬地区冷空气自北向南的侵袭通道上,更有利于较强冷空气入侵新疆。
Abstract:Based on the daily temperature data of Urumqi Meteorological Station from 1 January 1951 to 31 December 2015 and using daily minimum temperature and temperature drop range as the index, database of cooling process in Urumqi City ever the past 65 years is established. The cooling process is divided into 5 grades, i.e. Ⅰ (weak), Ⅱ (medium), Ⅲ (relatively strong), Ⅳ (strong), Ⅴ (cold wave). Some climate characteristics of cooling process are analyzed, such as frequency, continuous days, temperature drop range in different periods, minimum temperature, and anomaly of minimum temperature. The results show that: (1) From 1951 to 2015, there were 5834 cooling processes, annually 89.8 processes in average, of which 78.1% is of Grade Ⅰ (weak) cooling process. The seasonal distribution of the frequency of cooling process is uniform, but the largest number of Grade Ⅳ (strong) and Ⅴ (cold wave) cooling processes is in spring. Annual mean frequency of cooling process in the seven decades is not so different. Between the years with more and less cooling processes, the largest process frequency difference is in June-August, and the smallest difference is in April and September. With the decadal increases, the average annual frequency increased in Grade Ⅰ (weak) cooling process, and decreased in Grade Ⅴ (cold wave) process. (2) The continuous days of cooling process is 1.89 days in average and 49.0 % of the process lasts one day. The highest frequency of the continuous days changes from one day to three days as the grade changes from I (weak) to Ⅴ (cold wave). The continuous days of Grade Ⅳ (strong) and Ⅴ (cold wave) cooling processes are relatively more from late autumn to winter and less in spring. (3) The drop range of temperature of process is -4.4℃ in average and the largest drop in temperature is in autumn and the smallest drop in summer. The largest drop ranges of Grade Ⅳ (strong) and Ⅴ (cold wave) processes are in June and December. The maximum drop range of temperature in 24 h, 48 h and 72 h is -3.1℃,-5.5℃ and -7.4℃ in average, respectively. For 24 h, the largest temperature drop range happens in Spring and the smallest in winter. For 48 h, the largest drop is in spring and the smallest in summer. For 72 h, the largest drop is in winter and the smallest in summer. (4) The minimum temperature of the cooling process is 0.3℃ in average, the lowest is in winter and the hightest is in summer with distinct seasonal characteristics. The maximum daily temperature anomaly is -1.9℃ in average. As the grade changes from Ⅰ (weak) to Ⅴ (cold wave), the temperature anomaly gets much lower. The maximum daily temperature anomaly of Grade Ⅴ (cold wave) is -8.5℃. (5) During the months with more cooling processes in Urumqi, the 500 hPa high level is mainly controlled by zonal westerlies in Xinjiang Region, the short wave trough and east ridge with the stable westerlies affecting Xinjiang. In the abnormally less cooling process months, the 500 hPa high level is controlled by northwest airflow in Xinjiang Region, in the high latitudes of cold air from the north to the south channel, which is more favorable for the strong cold air to enter Xinjiang.
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基金项目:中央级公益性科研院所基本科研业务费专项资金项目(IDM201502)资助
引用文本:
毛炜峄,白素琴,陈鹏翔,2016.1951—2015年乌鲁木齐市降温过程频数及强度气候特征[J].气象,42(11):1351-1363.
MAO Weiyi,BAI Suqin,CHEN Pengxiang,2016.Climate Characteristics of Frequency and Intensity of Cooling Process in Urumqi During 1951-2015[J].Meteor Mon,42(11):1351-1363.