Variations in Total Ozone Observed at Longfengshan and Waliguan and Its Relationship with Synoptic Process

doi:10.13209/j.0479-8023.2015.003

›› 2015, Vol. 51 ›› Issue (4): 725-734.DOI: 10.13209/j.0479-8023.2015.003

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Variations in Total Ozone Observed at Longfengshan and Waliguan and Its Relationship with Synoptic Process

TU Xiaolin¹;ZHENG Xiangdong²;ZHAO Chunsheng¹

1. Department of Atmospheric Science, School of Physics, Peking University, Beijing 100871; 2. Chinese Academy of Meteorological Science, Beijing 100081;

Received:2014-04-03 Revised:2014-05-07 Online:2015-07-20 Published:2015-07-20
About author:ZHAO Chunsheng

龙凤山和瓦里关臭氧总量异常变化与天气过程关系研究

涂小林¹;郑向东²;赵春生¹

1. 北京大学物理学院大气与海洋科学系, 北京 100871; 2. 中国气象科学研究院, 北京 100081;

作者简介:赵春生
基金资助:
国家自然科学基金(40875014)资助

Abstract

Abstract: Longtime in-situ measurements of total ozone from the ground-based Brewer observatories at Longfengshan in Heilongjiang Province and Waliguan in Qinghai Province were analyzed together with the according geopotential height data from NCEP R1 reanalysis series. Abnormal day-to-day fluctuations in the total ozone amount were found at times, which were analyzed in respect to synoptic processes. Results show that the impact of synoptic conditions is highly related to the variation of the total ozone amount. The anomaly in total ozone amount mostly appears in winter and spring (from November to May in the following year). The abnormal high total ozone amounts (the first kind of abnormal data points) always occur when the station is at the rear of the near surface (1000 hPa) cyclone with a simultaneous air pressure trough approaching in lower stratosphere (250 to 70 hPa). The abnormal low total ozone amounts (the second kind of abnormal points) always occur when the station is behind a near surface anticyclone with a simultaneous air pressure ridges approaching in lower stratosphere. The anomaly in total ozone amount can be considered as a signal for the upcoming transition between near surface cyclone and anticyclone.

Key words: total ozone, abnormal points, synoptic process, corresponding relationship

摘要： 通过对黑龙江龙凤山和青海瓦里关Brewer 地基臭氧总量的长期观测资料以及与观测时段对应的全球 NCEP R1 系列位势高度再分析资料的统计分析发现, 龙凤山和瓦里关臭氧总量观测值有时存在剧烈的逐日变化, 对这种异常变化进行定量分析, 并对其与对流层天气过程的关系进行研究, 发现两者之间存在良好的对应关系。臭氧总量的异常变化大多数出现在11 月至次年5 月的冬、春季节, 并且臭氧总量的异常升高(第一类异值点)总是伴随着平流层低层(250~70 hPa)的槽线和地面(1000 hPa)的低压中心后方的天气形势, 而臭氧总量的异常降低(第二类异值点)则时常伴随平流层低层的脊线和地面的高压中心后方的天气形势, 这表明臭氧总量的异常变化可以作为地面天气系统转变的一个信号。

关键词: 臭氧总量, 异值点, 天气过程, 对应关系

CLC Number:

P402

TU Xiaolin;ZHENG Xiangdong;ZHAO Chunsheng. Variations in Total Ozone Observed at Longfengshan and Waliguan and Its Relationship with Synoptic Process[J]. , 2015, 51(4): 725-734.

涂小林;郑向东;赵春生. 龙凤山和瓦里关臭氧总量异常变化与天气过程关系研究[J]. 北京大学学报（自然科学版）, 2015, 51(4): 725-734.

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Variations in Total Ozone Observed at Longfengshan and Waliguan and Its Relationship with Synoptic Process

龙凤山和瓦里关臭氧总量异常变化与天气过程关系研究

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