中国珠江三角洲地区冬季臭氧垂直分布及其平流层向对流层输送分析

J. Sensors Pub Date : 2022-08-25 DOI:10.1155/2022/9771823
Cuihua Li, Yangbin Li, Jingman Peng, Ying Chen
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引用次数: 0

摘要

利用电化学浓度池(ECC)臭氧探空仪分析了2021年珠江三角洲冬季臭氧的垂直分布,并与激光雷达(LiDAR)臭氧探测与测距数据进行了对比。还探讨了平流层臭氧向对流层的输送。结果表明:(1)平流层臭氧层最大值约为25 km。平流层臭氧剖面以单峰型为主,且平流层臭氧含量远高于对流层。在对流层中,近地面(0 ~ 2 km)的臭氧含量略高于5 ~ 15 km。对流层中上层臭氧剖面呈峰型结构,主要分为单峰型(22%)和多峰型(77%)。(2)在对流层中下层,激光雷达探测到的臭氧垂直剖面与探测系统探测到的臭氧垂直剖面存在显著差异。在相同的高度,两者之间的差异从10 ppb到60 ppb不等。臭氧探测可以弥补激光雷达臭氧探测的近地面盲区,并对激光雷达的反演结果进行校正。(3) 2022年1月5日,平流层臭氧向对流层输送。平流层侵入是由于副热带急流中心在清远上空的高风速和强烈的沉降运动造成的。当平流层气团向对流层移动,遇到下沉气流时,近地面臭氧浓度在短时间内迅速升高。它被确定为“特殊事件”。
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Analysis of Vertical Distribution of Ozone in Winter and Its Transport from Stratosphere to Troposphere in the Pearl River Delta Region of China
The vertical distribution of winter ozone in the Pearl River Delta in 2021 was analyzed using electrochemical concentration cell (ECC) ozonesonde and compared with the ozone Light detection and ranging (LiDAR) data. The transport of stratospheric ozone to the troposphere was also explored. The results show that (1) the maximum value of the stratospheric ozone layer was about 25 km. The stratospheric ozone profile is mainly unimodal, and the stratospheric ozone content was much higher than that of the troposphere. In the troposphere, the ozone content near the ground (0-2 km) was slightly higher than that between 5 and 15 km. The ozone profile in the upper and middle troposphere showed a peak structure, which was mainly divided into single peak (22%) and multipeak (77%) profiles. (2) In the middle and lower troposphere, the vertical profile of ozone detected by LiDAR is significantly different from that detected by sounding system. The difference between the two ranged from 10 ppb to 60 ppb at the same height. Ozone sounding can supplement the blind area of the near-ground layer by LiDAR ozone detection and can calibrate the inversion results of LiDAR. (3) On January 5, 2022, stratospheric ozone was transported to the troposphere. The stratospheric intrusion occurred due the high wind speed of the subtropical jet centre over Qingyuan and due to strong subsidence movement. When the stratospheric air mass moved to the troposphere, and subsidence airflow encountered, the ozone concentration near the ground was rapidly increased in a short time. It was identified as an “exceptional event.”
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