青岛地区一次雾—霾过程能见度特征及影响因素分析

doi:10.3969/j.issn.1673-503X.2023.03.006

摘要/Abstract

摘要：

利用2021年11月16—20日青岛、平度、黄岛、胶州站的能见度等气象数据和邻近环境监测站PM_2.5浓度及水溶性离子浓度等观测数据, 分析了雾—霾过程中能见度的动态变化特征及其影响因素。结果表明: 2021年11月16—20日青岛整个雾霾过程大致经历了轻雾→干霾→湿霾→干霾→湿霾→干霾→湿霾→轻雾的转换, 地理位置差异导致内陆站点未经历轻雾阶段且霾阶段开始时间较沿海站提前8 h。雾、霾过程大气层结稳定且有一定的湿度条件, 地面风速≤2 m·s^-1, 垂直运动速度0.0~0.5 Pa·s^-1。偏东风携带的大量水汽、＞80%的湿度层变化是干霾、湿霾转化的重要因素。能见度随PM_2.5浓度、相对湿度的增加而逐渐下降, 相对湿度增大时能见度与PM_2.5浓度的相关性减小, 湿霾较干霾阶段PM_2.5浓度升高14.1%, 能见度下降47.4%, 霾转化为雾后能见度降低7.6%。在干霾阶段能见度的变化主要受PM_2.5浓度的影响; 在湿霾阶段能见度受PM_2.5浓度和相对湿度的共同影响; 在雾阶段能见度主要受相对湿度的影响。霾阶段SNA(SO₄^2-、NO₃^-、NH₄⁺)浓度、SOR(硫氧化率)、颗粒物中液态水含量随污染等级升高逐渐增加而能见度逐渐降低。从后向轨迹分析可以看出, 霾期间气团从内陆起源经江苏、河南等地到达青岛污染程度深, 雾期间气团经沿海地区到达青岛湿度大、污染程度小。

关键词: 雾霾, 相对湿度, PM_2.5, 水溶性离子

Abstract:

Taking Qingdao as an area of concern, this paper analyzes the dynamic change characteristics and influencing factors of visibility during the fog-haze process using meteorological data including visibility at Qingdao, Pingdu, Huangdao and Jiaozhou stations and observation data such as PM_2.5 concentration and water-soluble ion concentration at nearby environmental monitoring stations from November 16 to 20, 2021.The results show that the whole haze process in Qingdao from November 16 to 20, 2021 experienced the transitions of light fog, dry haze, wet haze, dry haze, wet haze, dry haze, wet haze, and light fog.Geographical discrepancies make the inland stations experience no light fog stage and the haze stage starting 8 hours earlier than the coastal stations.In the fog and haze process, the atmosphere appears stable junction and a certain humidity condition with the ground wind speed being less than 2 m·s^-1 and the vertical movement speed being 0.0~0.5 Pa·s^-1.The large amount of water vapor carried by the easterly wind and the variation of humidity layer above 80% are significant factors for the transition between dry and wet haze.Visibility gradually decreases with the enhancement of PM_2.5 concentration and relative humidity.When the relative humidity increases, the correlation between visibility and PM_2.5 concentration decreases.Compared with the dry haze stage, the PM_2.5 concentration in wet haze increases by 14.1%, visibility decreases by 47.4%, and visibility decreases by 7.6% after the transition from haze to fog.In the dry haze stage, visibility is significantly affected by the PM_2.5 level.In the wet haze stage visibility is affected by both PM_2.5 level and relative humidity, whereas in the fog phase visibility is significantly affected by relative humidity.In the haze stage, the SNA concentration (SO₄^2-, NO₃^-, NH₄⁺), SOR (sulfur oxidation rate), and liquid water content in particulate matter gradually increase with the enhancement of pollution level leading to visibility gradually decreasing.The backward trajectories indicate that during the haze period, the air masses originate from inland, passing through Jiangsu provrce, He'nan provice, and other places to Qingdao with a deep pollution degree, while during the fog period, the air masses reach Qingdao through the coastal areas with high humidity and low pollution degree.

Key words: Fog and Haze, Relative humidity, PM_2.5, Water-soluble ion

中图分类号:

P427.2

吕文丽,时晓曚,张凯. 青岛地区一次雾—霾过程能见度特征及影响因素分析[J]. 气象与环境学报, 2023, 39(3): 47-55.

Wen-li LÜ,Xiao-meng SHI,Kai ZHANG. Visibility characteristics and influencing factors of a fog-haze process in Qingdao[J]. Journal of Meteorology and Environment, 2023, 39(3): 47-55.

图/表 10

图1

图2

图3

图4

表1

图5

图6

表2

图7

图8

参考文献 32

1	Lyu R , Wang Y Y , Peng Y R , et al. Long-term variation characteristics and influencing factors of low-visibility events on the coast of China[J]. Atmospheric Research, 2021, 257, 105583. doi: 10.1016/j.atmosres.2021.105583
2	史珺, 赵玉洁. 天津市东丽区一次持续性雾霾天气过程的特征及影响要素分析[J]. 气象与环境学报, 2021, 37 (5): 8- 12.
3	尚倩. 南京冬季雾霾的宏微观特征及对能见度的影响[D]. 南京: 南京信息工程大学, 2012.
4	Yin Y , Wurzler S , Levin Z , et al. Interactions of mineral dust particles and clouds: effects on precipitation and cloud optical properties[J]. Journal of Geophysical Research: Atmospheres, 2002, 107 (D23): 4724.
5	Sun Y L , Zhuang G S , Tang A H , et al. Chemical characteristics of PM_2.5 and PM₁₀ in haze-fog episodes in Beijing[J]. Environmental Science & Technology, 2006, 40 (10): 3148- 3155.
6	Shang D J , Peng J F , Guo S , et al. Secondary aerosol formation in winter haze over the Beijing-Tianjin-Hebei Region, China[J]. Frontiers of Environmental Science & Engineering, 2021, 15 (2): 34.
7	李婷, 谭志强, 葛森, 等. 2018年8月22日宁夏北部局地浓雾天气形成机制分析[J]. 气象与环境学报, 2022, 38 (1): 8- 14.
8	Gao S H , Lin H , Shen B , et al. A heavy sea fog event over the Yellow Sea in March 2005:analysis and numerical modeling[J]. Advances in Atmospheric Sciences, 2007, 24, 65- 81. doi: 10.1007/s00376-007-0065-2
9	王赛頔, 阎琦, 王晓丽, 等. 辽宁地区一次罕见大雾天气成因分析[J]. 气象与环境学报, 2021, 37 (4): 122- 127. doi: 10.3969/j.issn.1673-503X.2021.04.017
10	Shen X J , Sun J Y , Zhang X Y , et al. Characterization of submicron aerosols and effect on visibility during a severe haze-fog episode in Yangtze River Delta, China[J]. Atmospheric Environment, 2015, 120, 307- 316. doi: 10.1016/j.atmosenv.2015.09.011
11	Xue Q , Lan Z , Lian S J , et al. Analysis of atmospheric visibility degradation in early haze based on the nucleation clustering model[J]. Atmospheric Environment, 2018, 193, 205- 213. doi: 10.1016/j.atmosenv.2018.09.019
12	时晓曚, 魏晓敏, 毕玮, 等. 青岛混合层高度变化特征及与空气污染的关系[J]. 山东气象, 2016, 36 (4): 1- 6. doi: 10.19513/j.cnki.issn1005-0582.2016.04.001
13	马艳, 黄容, 时晓曚, 等. 青岛冬季PM_2.5持续重污染天气的大气边界层特征[J]. 环境科学研究, 2018, 31 (1): 42- 52.
14	卢一凡, 王娇, 于铖浩, 等. 青岛市雾、霾天时空变化特征及影响因素分析[J]. 中国海洋大学学报, 2021, 51 (7): 34- 45.
15	中华人民共和国国家质量监督检验检疫总局, 中国国家标准化管理委员会. 雾的预报等级: GB/T 27964-2011[S]. 北京: 中国标准出版社, 2012.
16	中国气象局. 霾的观测和预报等级: QX/T 113-2010[S]. 北京: 气象出版社, 2010.
17	Yang Y C , Ge B Z , Chen X S , et al. Impact of water vapor content on visibility: fog-haze conversion and its implications to pollution control[J]. Atmospheric Research, 2021, 256, 105565. doi: 10.1016/j.atmosres.2021.105565
18	贺千山, 潘鹄, 黄颖, 等. 上海干霾与湿霾气溶胶消光特性的比较[J]. 兰州大学学报(自然科学版), 2013, 49 (4): 497- 503. doi: 10.3969/j.issn.0455-2059.2013.04.010
19	Xue B , Kuang Y , Xu W Y , et al. Joint increase of aerosol scattering efficiency and aerosol hygroscopicity aggravate visibility impairment in the North China Plain[J]. Science of the Total Environment, 2022, 839, 156279. doi: 10.1016/j.scitotenv.2022.156279
20	Fountoukis C , Nenes A . ISORROPIA Ⅱ: a computationally efficient thermodynamic equilibrium model for K⁺-Ca²⁺-Mg²⁺-NH₄⁺-Na⁺-SO₄^2--NO₃^--Cl^--H₂O aerosols[J]. Atmospheric Chemistry and Physics, 2007, 7 (17): 4639- 4659. doi: 10.5194/acp-7-4639-2007
21	Wang Y Q , Zhang X Y , Draxler R R . TrajStat: GIS-based software that uses various trajectory statistical analysis methods to identify potential sources from long-term air pollution measurement data[J]. Environmental Modelling & Software, 2009, 24 (8): 938- 939.
22	李蓓. 呼和浩特市雾霾天气气象条件分析与初步治理研究[D]. 呼和浩特: 内蒙古大学, 2020.
23	Parida B R , Bar S , Kaskaoutis D , et al. Impact of COVID-19 induced lockdown on Land Surface Temperature, aerosol, and urban heat in Europe and North America[J]. Sustainable Cities and Society, 2021, 75, 103336. doi: 10.1016/j.scs.2021.103336
24	Hong W , Xu J Y , Zhang M , et al. A study of the meteorological causes of a prolonged and severe haze episode in January 2013 over central-eastern China[J]. Atmospheric Environment, 2014, 98, 146- 157. doi: 10.1016/j.atmosenv.2014.08.053
25	Yao W X , Zheng Z M , Zhao J , et al. The factor analysis of fog and haze under the coupling of multiple factors-taking four Chinese cities as an example[J]. Energy Policy, 2020, 137, 111138.
26	Bergin M H , Cass G R , Xu J , et al. Aerosol radiative, physical, and chemical properties in Beijing during June 1999[J]. Journal of Geophysical Research: Atmospheres, 2001, 106 (D16): 17969- 17980.
27	Liu F , Tan Q W , Jiang X , et al. Effects of relative humidity and PM_2.5 chemical compositions on visibility impairment in Chengdu, China[J]. Journal of Environmental Sciences, 2019, 86, 15- 23.
28	Yang Y R , Liu X G , Qu Y , et al. Characteristics and formation mechanism of continuous hazes in China: a case study during the autumn of 2014 in the North China Plain[J]. Atmospheric Chemistry and Physics, 2015, 15 (14): 8165- 8178.
29	Bao F X , Jiang H Y , Zhang Y , et al. The key role of sulfate in the photochemical renoxification on real PM_2.5[J]. Environmental Science & Technology, 2020, 54 (6): 3121- 3128.
30	Han X , Zhang M G , Tao J H , et al. Modeling aerosol impacts on atmospheric visibility in Beijing with RAMS-CMAQ[J]. Atmospheric Environment, 2013, 72, 177- 191.
31	Huang X J , Liu Z R , Zhang J K , et al. Seasonal variation and secondary formation of size-segregated aerosol water-soluble inorganic ions during pollution episodes in Beijing[J]. Atmospheric Research, 2016, 168, 70- 79.
32	王建林, 时晓曚, 赵文雪, 等. 青岛地区一次雾霾重污染天气过程特征分析[J]. 气象科技, 2018, 46 (6): 1251- 1257.

雾霾类型	能见度/m	相对湿度/(%)	PM_2.5/(μg·m^-3)	液态水含量/(μg·m^-3)
轻雾	2361.9	97.2	54.1	/
湿霾	2558.1	87.5	119.3	174.9
干霾	4862.0	63.7	104.6	67.5

污染状况	能见度/m	Ca²⁺/(μg·m^-3)	Mg²⁺/(μg·m^-3)	NH₄⁺/(μg·m^-3)	Na⁺/(μg·m^-3)	SO₄^2-/(μg·m^-3)	NO₃^-/(μg·m^-3)	Cl^-/(μg·m^-3)
优良	4053.8	0.07	0.03	10.86	0.04	7.22	27.88	1.01
轻度污染	2988.5	0.09	0.02	15.22	0.05	8.49	41.87	1.08
中度污染	2271.7	0.08	0.02	20.17	0.07	11.55	54.64	1.03
湿霾	2558.1	0.09	0.03	14.46	0.05	8.03	39.89	0.99
干霾	4862.0	0.07	0.02	16.70	0.06	9.82	44.86	1.07

[1]	张煦庭, 刘慧, 刘瑞芳, 巨菲, 刘嘉慧敏, 高星星, 黄少妮, 王楠. 基于极端梯度提升算法的西安市逐小时PM_2.5浓度预报研究[J]. 气象与环境学报, 2023, 39(1): 44-54.
[2]	朱刚,李江波,孙卓,王硕飞. 能见度观测方式改变对京津冀地区雾霾判识及统计的影响分析[J]. 气象与环境学报, 2023, 39(1): 55-64.
[3]	马瑞丰,许敬红,严良政. 2013—2018年大连中心城区臭氧时空变化及其影响因子分析[J]. 气象与环境学报, 2022, 38(3): 75-84.
[4]	肖袁俊,李保山,宋文丹,程勇翔,黄敬峰. 1998—2016年中国PM_2.5浓度变化对气温的影响研究[J]. 气象与环境学报, 2022, 38(3): 85-92.
[5]	刘美,姬兴杰,田力,丁亚磊,左璇. 1961—2020年郑州主城区大气自净能力变化特征分析[J]. 气象与环境学报, 2022, 38(3): 93-100.
[6]	王学强,董慧杰. 一次中尺度对流风暴造成的内蒙古局地沙尘天气过程分析[J]. 气象与环境学报, 2021, 37(6): 11-19.
[7]	史珺, 赵玉洁. 天津市东丽区一次持续性雾霾天气过程的特征及影响要素分析[J]. 气象与环境学报, 2021, 37(5): 8-12.
[8]	尹浩, 郯俊岭, 王巨勇, 李洪权, 奚雷, 吴彬, 邱吉东. 湖州市PM_2.5浓度变化及传输特征分析[J]. 气象与环境学报, 2021, 37(5): 20-26.
[9]	代玉田, 杨学斌. 2018年冬季鲁西北大气污染特征及影响因子分析[J]. 气象与环境学报, 2021, 37(4): 40-47.
[10]	栾兆鹏,卢慧超,李恬,崔向前,赵天良,朱庆瑞. 降水和风对泰安地区PM_2.5浓度的影响及区域传输研究[J]. 气象与环境学报, 2021, 37(3): 33-39.
[11]	袁湘玲, 马虹旭, 陈石定, 刘春芳. 黑龙江省闪电活动特征及其与地面相对湿度的响应关系[J]. 气象与环境学报, 2020, 36(5): 91-96.
[12]	郭凤娟,李春花,窦春苓. 克拉玛依市PM_2.5质量浓度分布及其影响因素分析[J]. 气象与环境学报, 2020, 36(4): 52-58.
[13]	闫平,季生太,孙彦坤,姜丽霞,王秋京,吕佳佳,王萍. 富裕县农田土壤湿度变化及其对玉米发育期和产量的影响[J]. 气象与环境学报, 2020, 36(4): 74-82.
[14]	王秀玲,花家嘉,李轩,马前进,王冠,李衡,曹晓霞. 2015—2017年唐山市PM_2.5重污染生消气象条件分析[J]. 气象与环境学报, 2020, 36(4): 45-51.
[15]	王振,杨卫芬,叶香,李艳萍,夏京,李春玉,何涛. 气象因素对常州市区PM_2.5浓度影响[J]. 气象与环境学报, 2020, 36(3): 26-32.