北京地区大气臭氧与氮氧化物测量分析

大气与环境光学学报 ›› 2012, Vol. ›› Issue (5): 321-326.

• 大气光学 • 下一篇

北京地区大气臭氧与氮氧化物测量分析

张世国1,2,苑克娥*1,胡顺星1 ,黄见1,王英俭1

（1 中国科学院安徽光学精密机械研究所中国科学院大气成分与光学重点实验室，安徽合肥 230031；
2 中国科学院研究生院，北京 100039）

收稿日期:2012-05-11 修回日期:2012-05-29 发布日期:2012-10-21
通讯作者: 张世国（1986-），男，硕士研究生，主要从事激光雷达大气痕量气体检测新方法新技术研究以及数据仿真计算工作. E-mail:zhangshiguo1124@126.com
作者简介:张世国（1986-），男，硕士研究生，主要从事激光雷达大气痕量气体检测新方法新技术研究以及数据仿真计算工作.
基金资助:
科技部基础性工作专项重点项目（2007FY110700）、中科院知识创新方向性项目（KJCX2-EW-N07）、国家自然科学基金（41005015）资助

Analysis for Atmospheric Ozone and Nitrogen Oxide in Beijing Area

ZHANG Shi-guo1,2,YUAN Ke-e1, HU Shun-xing1, HUANG Jian 1,WANG Ying-jian1

(1 Key Laboratory of Atmospheric Composition and Optical Radiation, Anhui Institute of Optics and Fine Mechanics, Chinese Academy of Sciences, Hefei 230031, China;
2 Graduate University of Chinese Academy of Sciences, Beijing 100039, China)

Received:2012-05-11 Revised:2012-05-29 Online:2012-10-21

摘要/Abstract

摘要：

高层大气臭氧能够吸收紫外线保护地球生物，但是低空和近地面臭氧却是危害人类健康和动植物生长的污染气体。氮氧化物也是空气中的污染气体，臭氧和氮氧化物可以相互转化，研究二者的变化关系具有重要意义。2011年12月利用EC9810A臭氧分析仪和EC9841氮氧化物分析仪，在北京中国环境科学研究院进行测量，得到了臭氧和氮氧化物的变化特征，分析结果表明臭氧和氮氧化物具有日变化特征，白天臭氧浓度呈现先上升后下降的趋势，夜里比较平稳;氮氧化物与臭氧变化趋势呈负相关，白天浓度先下降后升高，夜间浓度大于白天;臭氧的变化与气象条件有关，在晴天上升较快，峰值大，阴天上升慢，峰值小;臭氧的含量还具有明显的季节特征，春季的浓度要比冬季的浓度高。氮氧化物的变化与人们的生活关系密切，汽车尾气等废气的排放是导致氮氧化物含量升高的重要原因。同时利用中科院安徽光机所研制的AML-3车载激光雷达测量了臭氧在白天垂直高度上的分布，在500~1000 m高度上臭氧的平均含量变化与分析仪测量趋势比较一致。

关键词: 臭氧, 氮氧化物, 光化学作用, 车载激光雷达

Abstract:

At upper atmosphere, ozone can absorb ultraviolet and protect life on earth, but at low altitude and near-ground ozone is polluting gas endangering human health, animal and plant growth. Nitrogen oxides are also polluting gases in the air. Ozone and nitrogen oxides can be transformed into each other. Research on the relationship between the two gas is of great significance. Based on EC9810A ozone analyzer and EC9841 nitrogen oxide analyzer, the observation at Chinese Research Academy of Environment Sciences in Beijing during December, 2011 is carried out, and the distributed characteristics of ozone and nitrogen oxide during day and night were obtained. The analysis shows obvious distributed characteristics of ozone and nitrogen oxide during day and night. At daytime, concentration of ozone increases at morning, and then decreases at afternoon. At night, it keeps a steady status and the concentration is less than that in daytime. The trend of nitrogen oxide is opposite to ozone. At daytime, the concentration of nitrogen oxide decreases at morning and then increases at afternoon. The change of ozone has the relationship with meteorology. On sunny day, the concentration of ozone has a sharp increase, but at cloudy day or rainy day, has a slow increase. And the concentration of ozone also changes with the season, it is higher in spring than that in winter. The main reason that results in the concentration increase of nitrogen oxide is the emission of automobile exhaust and other waste gas. AML-3 mobile lidar developed by Anhui Institute of Optics and Fine Mechanics, Chinese Academy of Sciences is used to measure the vertical profile. Variation of mean ozone concentrations from 500 m to 1000 m has a consistent trend with ozone analyzer.

Key words: ozone, nitrogen oxide, photochemical reaction, mobile lidar

中图分类号:

P412

张世国苑克娥胡顺星黄见王英俭. 北京地区大气臭氧与氮氧化物测量分析[J]. 大气与环境光学学报, 2012, (5): 321-326.

ZHANG Shi-Guo, YUAN Ke-E, HU Shun-Xing, HUANG Jian, WANG Ying-Jian. Analysis for Atmospheric Ozone and Nitrogen Oxide in Beijing Area[J]. Journal of Atmospheric and Environmental Optics, 2012, (5): 321-326.

参考文献

[1]Terje B．Impact of increased anthropogenic emission in Asia on tropospheric ozone and climate [J].Tellus, 1996, 48B: 13-32.
[2] Mazeeo N A, Venegas L E, Choren H. Analysis of NO,NO2,O3 and NOx concentration measured at a green air of Buenos Aires City during wintertime [J]. Atmosphere Environment, 2005, 39(17): 3055-3068.
[3] Clapp L J, Jenkin M E. Analysis of the relationship between ambient levels of O3,NO2 and NO as a function of NOx in the UK [J]. Atmosphere Environment, 2001, 35(36): 6391-6405.
[4] Sun Jingqun. Laser Atmospheric Detection [M]. Beijing: Science Press, 1986: 9-10(in Chinese).
孙景群. 激光大气探测 [M]. 北京: 科学出版社, 1986: 9-10.
[5]Meng Xiangqian, Hu Shunxing, Cao Kaifa, et al. Analysis of ozone and aerosol data measurement at Dabie Mountain and Hefei Suburb Regions [J]. Journal of Atmospheric and Environmental Optics, 2011, 6(1): 75-82(in Chinese).
孟祥谦, 胡顺星, 曹开法, 等. 大别山区和合肥城郊地面臭氧、气溶胶测量结果分析 [J]. 大气与环境光学学报, 2011, 6(1): 75-82.
[6]Wang Shaolin, Xie Pinhua, Hu Shunxing, et al. Measurement of atmospheric boundary layer pollutants by mobile lidar in Beijing [J]. Environment Science, 2008, 29(3): 562-568(in Chinese).
汪少林, 谢品华, 胡顺星, 等. 车载激光雷达对北京地区边界层污染监测研究 [J]. 环境科学, 2008, 29(3): 562-568.
[7] Bai Jianhui, Wang Mingxing. The analysis for the variation characteristics of surface ozone and NOx in Dinghushan Station [J]. Acta Scientiae Circumstantiae, 1999, 19(3): 262-265(in Chinese).
白建辉, 王明星. 鼎湖山地面臭氧、氮氧化物变化特征的分析 [J]. 环境科学学报, 1999, 19(3): 262-265.
[8] An Junlin, Wang Yuesi, Li Xin, et al. Analysis of the reltionship between NO, NO2 and O3 concentrations in Beijing [J]. Environment Science, 2007, 28(4): 706-711(in Chinese).
安俊琳, 王跃思, 李昕, 等. 北京大气中NO、NO2 和 O3 浓度变化的相关性分析 [J]. 环境科学, 2007, 28(4): 706-711.

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北京地区大气臭氧与氮氧化物测量分析

Analysis for Atmospheric Ozone and Nitrogen Oxide in Beijing Area

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