北京市夏季不同O3和PM2.5污染状况研究

从天气背景场、气象要素、前体物和PM_(2.5)化学组分、气团运动轨迹以及大气氧化性等方面对北京市夏季两种不同的O_3和PM_(2.5)污染状况进行了分析.结果表明,O_3达到中度污染而PM_(2.5)浓度优良(O_3和PM_(2.5)一高一低)污染状况的天气形势场为:高空为偏西北气流,地面受高压后部控制;而O_3和PM_(2.5)同时达到中度污染(O_3和PM_(2.5)两高)的天气形势场为:高空为偏西气流,地面受低压控制.与O_3和PM_(2.5)一高一低污染状况相比,O_3和PM_(2.5)两高时的气象要素特征为:偏南风更为明显和相对湿度更高.O_3和PM_(2.5)两高时污染物浓度演变特征为,O_3和PM_(2.5)的起始浓度较高,PM_(2.5)日变化特征更为明显,而O_3平均浓度却低于O_3和PM_(2.5)一高一低的污染状况.前体物、大气氧化性以及PM_(2.5)化学组分分析的结果表明,较高的起始浓度在不利气象条件下的积累和吸湿增长以及当天较大偏南风造成的区域传输可能是造成O_3和PM_(2.5)两高污染状况中PM_(2.5)浓度达到四级中度污染的主要原因.     

南京地区近地面臭氧浓度与气象条件关系研究

通过分析2013—2015年南京地区相关气象要素对近地面臭氧浓度的影响,建立了用于不同季节高浓度臭氧污染事件的预报预警模型,并归纳总结了南京地区高浓度臭氧出现的天气形势.结果表明,近地面臭氧浓度的变化与气象要素密切相关,气温、能见度、日照小时、总(净)辐射辐照度等要素与O_3浓度呈显著正相关,与相对湿度、总(低)云量呈负相关.高浓度臭氧污染是多因子综合作用的结果,典型气象条件表现为:太阳辐射强,低云量少,相对湿度适宜,地面小风速及特定的风向.通过定义高浓度臭氧潜势指数HOPI和风向指数WDI,并综合考虑14:00地面气温、相对湿度及8:00各标准层的相关气象要素,建立了逐季节多指标叠套的高浓度臭氧预报方程.采用2016年资料对其进行检验,发现预报值与观测值的相关系数分别达0.72(冬季)、0.76(春季)和0.73(夏季),说明方程具有较好的拟合效果和可预报性.通过普查历史天气图,归纳了伴随南京地区高浓度臭氧事件出现的8种主要天气形势,即高压类(高压中心G0、高压后部G1)、低压类(低压底部D0、低压前部D1、低压倒槽D2)、均压类(高压相关的均压JG、低压相关的均压JD、其它均压J).其中,以高压后部地面形势出现概率最大,低压前部均压场出现时对应臭氧平均浓度最高.     

济南大气臭氧浓度变化规律

利用近2a济南市区近地面大气O₃浓度的观测数据,分析了O₃浓度的分布特征及时间变化规律.结果表明,济南市区O₃浓度以1a为周期呈明显的波动变化特征,城市光化学污染较重;1d当中O₃浓度呈明显的单峰型变化,一般在午后达到最高值,而日出时分出现最低值;春季和夏季O₃浓度高于秋季和冬季,而夏季和秋季O₃浓度的日内变化幅度明显高于春季和冬季;受人们活动规律的影响,周末O₃浓度的日内变化规律与平日有所不同.     

Comparative study of seasonal air pollutant behavior in a Mediterranean coastal site: Castellón (Spain)

During January, July and August 1988, two experimental campaigns were carried out in the surroundings of the Castellón industrial area located on the Spanish east coast. The main objective was to study the dispersion of the power plant plume located on this site. This work also forms part of a larger program intended to compose a mosaic of atmospheric mesoscale flows related to air pollution cycles for the whole of the Iberian peninsula.In this program, air pollutants have also been considered as tracers of opportunity of the atmospheric circulations, and the study of ground-level concentration cycles has been used to provide evidence for the meso-meteorological processes. On the Castellón coast, and for most of the year, surface atmospheric dynamics are dominated by local cycles of north-west nocturnal drainage winds and east to south-south-east daytime sea-breeze flows. This regime is particularly marked during the summer, while the effect of large scale synoptic conditions is more noticeable in winter and spring.A mobile laboratory was used to collect 10 min averaged values of O₃, NO, NO₂, and SO₂. This unit was placed in the expected zone of influence of the coastal industries during the sea-breeze regime. Data obtained under summer and winter conditions have been compared and, while the temporal evolution of the concentrations of the compounds studied have similar structures, high ozone values have been detected in association with the onset of the sea-breeze during the summer.     

Seasonal,diurnal and nocturnal variations of carbonyl compounds in the semi-urban environment of Orléans,France

Atmospheric carbonyls were measured at a semi-urban site in Orléans, France, from October 2010to July2011. Formaldehyde, acetaldehyde and acetone were found to be the most abundant carbonyls, with average concentrations of 3.1, 1.0, 2.0 ppb, respectively in summer, 2.3, 0.7, 2.2 ppb, respectively in autumn, 2.2, 1.0, 2.1 ppb, respectively in spring,and 1.5, 0.7, 1.1 ppb, respectively in winter. Photo-oxidation of volatile organic compounds(VOCs) was found to make a remarkable contribution to atmospheric carbonyls in the semi-urban site based on the distinct seasonal and diurnal variations of the carbonyls, as well as the significantly positive correlations between the carbonyls and ozone. The significantly negative correlations between NO x and O_3 as well as the carbonyls and the positive correlations between wind speed and O_3 as well as the carbonyls implied that the carbonyls and O_3 at the semi-urban site were probably formed during air mass transport from neighboring cities.     

北京地区边界层大气臭氧浓度变化特征分析

利用2001-03～2006-10的大气臭氧探空资料,分析了近6 a北京边界层（2 km以下）大气臭氧浓度的平均月变化和季节变化规律.结果表明,边界层大气臭氧浓度的月变化很明显,1月臭氧浓度最小,地面臭氧浓度不到10×10^-9(体积分数,下同),上层（即2 km）臭氧浓度也不到50×10^-9.而6月臭氧浓度最大,地面达到85×10^-9,上层大于90×10^-9.臭氧浓度具有明显的季节特征,从臭氧浓度值来看,冬季最小,夏季最大.从地面到上层的臭氧浓度的变化幅度来看,冬季变化最大,夏季变化最小.根据廓线变化方式,臭氧浓度廓线可分为3种类型,冬季型、夏季型、春秋季型.不同高度臭氧月平均浓度也明显不同.分析地面及上层臭氧浓度与气象因子如温度和湿度的相关关系,发现地面臭氧浓度与温度具有较好的线性关系,相关系数在0 .85以上.     

Transpiration rates of urban trees, Aesculus chinensis

Transpiration patterns of Aesculus chinensis in relation to explanatory variables in the microclimatic, air quality, and biological phenomena categories were measured in Beijing, China using the thermal dissipation method. The highest transpiration rate measured as the sap flux density of the trees took place from 10:00 am to 13:00 pm in the summer and the lowest was found during nighttime in the winter. To sort out co-linearity, principal component analysis and variation and hierarchical partitioning methods were employed in data analyses. The evaporative demand index (EDI) consisting of air temperature, soil temperature, total radiation, vapor pressure deficit, and atmospheric ozone (O₃), explained 68% and 80% of the hourly and daily variations of the tree transpiration, respectively. The independent and joint effects of EDI variables together with a three-variable joint effect exerted the greatest influences on the variance of transpiration rates. The independent effects of leaf area index and atmospheric O₃ and their combined effect exhibited minor yet significant influences on tree transpiration rates.     

冬小麦田O3气孔与非气孔沉降及风险评估

为了深入了解农田生态系统的O_3干沉降过程,并基于O_3通量(尤其是气孔O_3累积通量)指标进行风险评估,利用涡度相关系统对冬小麦田的O_3干沉降过程进行了连续动态观测,初步分析O_3浓度和总O_3通量的变化过程,着重探析气孔O_3沉降和非气孔O_3沉降的变化特征及其与主要气象因子的关系,并基于剂量指标(AOT40)和通量指标(DF_s06)分别推算出冬小麦的产量损失率.结果表明,观测期间(自2016年3月16日至5月30日)日平均O_3浓度(cO_3)为32.9 n L·L-1;白天(08:00~18:00)和夜间平均总O_3通量(F_(O3))分别为-7.6 nmol·(m~2·s)~(-1)和-3.1 nmol·(m~2·s)~(-1),日均F_(O3)为-5.1nmol·(m~2·s)~(-1).逐日平均气孔O_3通量(F_s)的变化范围为0~-5.1 nmol·(m~2·s)~(-1),日均F_s为-1.43 nmol·(m~2·s)~(-1).逐日平均非气孔O_3通量(F_(ns))的变化范围为-1.43~-10.31 nmol·(m~2·s)~(-1),日均F_(ns)为-3.66 nmol·(m~2·s)~(-1).较强的太阳辐射(SR)、较高的温度(T)和适度湿润的条件有利于冬小麦气孔沉降;较强的SR、适度的T和湿润条件是有利于冬小麦非气孔沉降.在整个观测期间,总O_3累积吸收通量(DF_(O3))、气孔O_3累积吸收通量(DF_s)和非气孔O_3累积吸收通量(DF_(ns))分别为31.58、9.99和21.59 mmol·m~(-2),总DF_s和总DF_(ns)分别占总DF_(O3)的32%和68%.通过剂量指标AOT40和通量指标DF_s06响应方程计算出的冬小麦产量损失率分别为11.58%~20.37%和20%~23.56%.     

南京北郊O3、NO2和SO2浓度变化及长/近距离输送的影响

利用2008年1月—2010年12月南京北郊O₃、NO₂和SO₂质量浓度连续观测资料结合后向轨迹模式,采用聚类分析对轨迹进行分类和KZ滤波器对数据组分进行分离的方法,讨论了南京北郊气体污染物(O₃、NO₂和SO₂)的质量浓度变化规律及长/近距离输送对该地区污染气体的影响.结果表明,南京北郊春末夏初(5、6月)O₃月均浓度出现最大值,12月出现最小值;NO₂在春季(3—5月)月平均浓度相对较高,8月份浓度全年最低,而SO₂浓度在6、7月出现最低值.不同季节气体污染物浓度日变化各有特点,O₃呈单峰分布,12:00—15:00出现浓度最大值;NO₂浓度高值则出现在夜间;SO₂在清晨出现最大值,另外,春秋冬季SO₂呈双峰型分布.长/近距离输送对南京北郊污染气体影响的分析表明,在西南方向的近距离输送影响下,该地区O₃浓度将会出现明显的高值;传输速度较慢的西北气流则会促使该地区形成高浓度的NO₂;长距离输送对O₃和NO₂的贡献与气团输送距离有关,说明该地区O₃和NO₂是区域性问题.另外,当在传输速度较慢的偏东气流的控制下,SO₂的浓度较高,说明SO₂的高浓度事件与偏东方向的近距离输送有关.     

Climate-driven changes in air quality over Europe by the end of the 21st century,with special reference to Portugal

Climate change alone may deeply impact air quality levels in the atmosphere because the changes in the meteorological conditions will induce changes on the transport, dispersion and transformation of air pollutants. The aim of this work was to evaluate the impact of climate change on the air quality over Europe and Portugal, using a reference year (year 1990) and a IPCC SRES A2 year (year 2100). The Hadley Centre global atmospheric circulation model (HadAM3P) was used to provide results for these two climatic scenarios, which were then used as synoptic forcing for the MM5-CHIMERE air quality modelling system. In order to assess the contribution of future climate change on O₃ and PM concentrations, no changes in regional emissions were assumed and only climate change forcing was considered. The modelling results suggest that the O₃ monthly mean levels in the atmosphere may increase almost 50 μg m^?3 across Europe in July under the IPCC SRES A2 scenario. In Portugal, this increase may reach 20 μg m^?3. The changes of PM10 monthly average values over Europe will depend on the region. The increase in PM10 concentrations during specific months could be explained by the average reduction of the boundary layer height and wind speed.     

Observations of atmospheric pollutants at Lhasa during 2014–2015: Pollution status and the influence of meteorological factors

Atmospheric pollutants including SO₂, NO₂, CO, O₃ and inhalable particulate matter (PM_2.5 and PM₁₀) were monitored continuously from March 2014 to February 2015 to investigate characteristics of air pollution at Lhasa, Tibetan Plateau. Species exhibited similar seasonal variations except O₃, with the peaks in winter but low valleys in summer. The maximum O₃ concentration was observed in spring, followed by summer, autumn, and winter. The positive correlation between O₃ and PM₁₀ in spring indicated similar sources of them, and was assumed to be turbulent transport. Temperature was the dominant meteorological factor for most species in spring. High temperature accelerates O₃ photochemistry, and favors air disturbance which is conductive to dust resuspension in spring. Relative humidity (RH) and atmospheric pressure were the main meteorological factors in summer. RH showed negative correlations with species, while atmospheric pressure posed opposite situation. Wind speed (WS) was the dominant meteorological factor in autumn, the negative correlations between WS and species indicated diffusion by wind. Most species showed non-significant correlations with meteorological factors in winter, indicating the dependence of pollution on source emission rather than restriction by meteorology. Pollution weather character indicated that emissions were from biomass burning and dust suspension, and meteorological factors also played an important role. Air stream injection from the stratosphere was observed during O₃ pollution period. Air parcels from Southwest Asia were observed during air pollution period in winter. An enhancement in air pollutants such as O₃ would be expected in the future, more attention should be given to countermeasures for prevention of air pollution in the future.     

北京气象塔夏季大气O3,NOx和CO浓度变化的观测实验

以北京325m气象塔为观测平台,于2002年夏季进行了大气污染物臭氧(O₃)及其前体物氮氧化物(NO_x)和气象要素加强期的同步观测.对观测资料做了详尽的分析,结果表明:边界层内存在明显的臭氧浓度(用体积分数表示)垂直差异;中午120m高度层存在O₃浓度最大值;低层O₃浓度呈明显的日变化,且昼夜振幅较大;夜间高层(280m)O₃的湍流混合和化学消耗较弱,可维持较高的浓度;局地光化学生成是白天边界层O₃的主要来源;降水天气过程可造成O₃及其前体物浓度的显著变化.     

南京夏季大气臭氧光化学特征与敏感性分析

对流层臭氧（O₃）主要由氮氧化物（NO_x）和挥发性有机物（VOCs）经过一系列光化学反应生成,反应过程呈现复杂的非线性关系.为深入了解O₃的光化学特征及生成机制,利用2018年夏季大气O₃与VOCs的观测数据,结合大气零维框架模拟模型F0AM-MCM,研究O₃超标日和非O₃超标日的O₃光化学特征之间的差异性.观测结果表明,O₃超标日期间φ（O₃）和φ（TVOCs）的平均值分别为47.8×10^-9和49.0×10^-9,为非O₃超标日期间O₃（26×10^-9）和TVOCs（30×10^-9）体积分数的1.8倍和1.6倍.使用F0AM模型,借助EKMA曲线和RIR分析等识别O₃敏感性,发现南京市O₃超标日和非O₃超标日O₃的形成均主要受VOCs和NO_x的协同控制.F0AM-MCM模拟结果表明,在O₃超标日,·OH和HO₂的日平均混合比分别是非O₃超标日的1.3倍和1.8倍,表明O₃超标日期间具有更强的大气氧化能力,且·OH和HO₂的形成和损失速率也有明显的增加,表明自由基循环的增强.此外,O₃超标日的O₃生成速率明显高于非O₃超标日,从而导致了O₃超标日的O₃净生成速率明显高于非O₃超标日.以上发现提高了对南京夏季O₃超标日大气O₃光化学特征的认识.     

Air pollutant concentrations in Varanasi,India

This study reports the diurnal patterns in the concentrations of ozone (O₃), nitrogen dioxide (NO₂), sulphur dioxide (SO₂) and total suspended particulate matter (TSP) in the urban atmosphere of Varanasi city in India during 1989. The city was divided into five zones and three monitoring stations were selected in each zone.Ambient concentrations of NO₂ and SO₂ were maximum during winter but ozone and TSP concentrations were highest during summer. The measured maximum concentrations (2-h average) were 150 and 231 μg m⁻³ (0.078 and 0.086 ppm) for NO₂ and SO₂, respectively, for the winter season. Ozone and TSP concentrations reached a maximum of 160 (0.08 ppm) and 733 μg m⁻³, respectively, in the summer. NO₂ and SO₂ concentrations peaked in the morning and evening. Peak concentrations of O₃ occurred in the afternoon, generally between noon and 4 p.m. Maximum concentrations of O₃, NO₂, SO₂ and TSP were measured in zones I and II, and minimum in zone V.     

基于复杂网络的中国臭氧拓扑特征

伴随着颗粒物浓度的快速下降,大气臭氧（O₃）污染呈快速上升和蔓延态势,已成为制约我国空气质量持续改善的瓶颈问题之一.因此,理清O₃浓度变化特征对于改善空气质量有重要意义.应用复杂网络方法,基于城市间O₃浓度的相关关系和其时滞,构建中国O₃浓度网络,并分析O₃浓度的关联结果和传输特征.结果表明,统计指标度、加权度和连边长度的概率密度函数遵循幂律分布,这说明O₃浓度的变化不是随机的,存在一定的规律性.加权度的空间分布分析表明,加权度的高值集中在京津冀和周边地区,与O₃浓度高值区分布一致.其中,北京、天津和河北东部（渤海湾沿线）城市向其他城市传输的能力较强.并且,冬季传输能力强于其它季节,主要是受到冬季风的影响.研究结果不仅有助于理解O₃浓度变化特征,也是复杂网络方法应用到大气环境中的有益尝试.     

Relationships between chemical elements of PM2.5 and O3 in Shanghai atmosphere based on the 1-year monitoring observation

Mass level of fine particles (PM_2.5) in main cities in China has decreased significantly in recent years due to implementation of Chinese Clean Air Action Plan since 2013, however, O₃ pollution is getting worse than before, especially in megacities such as in Shanghai. In this work, O₃ and PM_2.5 were continuously monitored from May 27, 2018 to March 31, 2019. Our data showed that the annual average concentration of PM_2.5 and O₃ (O₃-8 hr, maximum 8-hour moving average of ozone days) was 39.35 ± 35.74 and 86.49 ± 41.65 µg/m³, respectively. The concentrations of PM_2.5 showed clear seasonal trends, with higher concentrations in winter (83.36 ± 18.66 µg/m³) and lower concentrations in summer (19.85 ± 7.23 µg/m³), however, the seasonal trends of O₃ were different with 103.75 ± 41.77 µg/m³ in summer and 58.59 ± 21.40 µg/m³ in winter. Air mass backward trajectory, analyzing results of potential source contribution function model and concentration weighted trajectory model implied that pollutants from northwestern China contributed significantly to the mass concentration of Shanghai PM_2.5, while pollutants from areas of eastern coastal provinces and South China Sea contributed significantly to the mass level of ozone in Shanghai atmosphere. Mass concentration of twenty-one elements in the PM_2.5 were investigated, and their relationships with O₃ were analyzed. Mass level of ozone had good correlation with that of Ba (r = 0.64, p < 0.05) and V (r = 0.30, p > 0.05), suggesting vehicle emission pollutants contribute to the increasing concentration of ozone in Shanghai atmosphere.     

中国典型城市O3与前体物变化特征及相关性研究

为了解我国不同气候背景城市O₃污染及其与前体物的关系,选取北京市、沈阳市、银川市、成都市、南京市和广州市作为典型代表城市,基于这6个城市2014-2016年ρ（O₃）、ρ（NO₂）和ρ（CO）资料对O₃与其前体物质量浓度变化特征及二者相关性进行研究.结果表明:①2014-2016年6个城市ρ（O₃）年均值大小顺序依次为南京市>沈阳市>北京市>银川市>成都市>广州市,ρ（NO₂）年均值大小顺序依次为北京市>成都市>南京市>沈阳市>广州市>银川市,ρ（CO）年均值大小顺序依次为北京市>银川市>成都市>沈阳市>南京市>广州市.2014-2016年除广州市ρ（O₃）下降、沈阳市变化不明显外,其他城市ρ（O₃）总体呈上升趋势;各城市ρ（NO₂）和ρ（CO）普遍呈下降趋势.②广州市ρ（O₃）夏季最高、春季最低,其他城市四季ρ（O₃）大小顺序依次为夏季>春季>秋季>冬季;北京市、沈阳市和银川市四季ρ（NO₂）和ρ（CO）大小顺序依次为冬季>秋季>春季>夏季,成都市、广州市和南京市为冬季>春季>秋季>夏季.各城市ρ（O₃）和ρ（O_x）日变化呈单峰型,ρ（NO₂）和ρ（CO）日变化呈双峰型.③6个城市城区ρ（O₃）均低于清洁对照点,城区ρ（NO₂）和ρ（CO）均高于清洁对照点,并且城区与清洁对照点O₃及其前体物质量浓度差值随城市和月份变化存在一定的差异.④各城市ρ（O₃）与ρ（NO₂）和ρ（CO）均呈负相关,与ρ（O_x）呈显著正相关;城区ρ（O₃）与ρ（NO₂）和ρ（CO）的相关性均好于清洁对照点,清洁对照点ρ（O₃）与ρ（O_x）的相关性则好于城区.⑤各城市ρ（O₃）超标率随ρ（NO₂）和ρ（CO）的增加均呈先迅速上升再快速减小,之后缓慢变化的特征,但ρ（O₃）超标率峰值对应的ρ（NO₂）和ρ（CO）有所差异.研究显示,日照条件较好的银川市、北京市和沈阳市O₃与其前体物相关性较成都市、南京市和广州市强.      

海陆风对天津市PM2.5和O3质量浓度的影响

静稳天气下局地环流往往会对污染物的传输扩散起重要作用.根据天津市地处渤海西岸,常年受到海陆风影响的特点,综合气象、环境资料及HYSPLIT模型,针对沿海、市区、城郊、山区等代表性站点,研究了海陆风对天津市ρ（PM_2.5）和ρ（O₃）的影响.结果表明:①2015年天津市海陆风天数为78 d,占全年的22%;海陆风多集中于6-9月,其中,7月海陆风日最多、2月最少.②ρ（PM_2.5）和ρ（O₃）季节性变化和空间分布特征不同.春、夏两季ρ（PM_2.5）山区最高、城郊最低;秋、冬两季ρ（PM_2.5）市区最高、山区最低.春、秋两季ρ（O₃）沿海最高、市区最低;夏季ρ（O₃）山区最高、沿海最低.③海陆风对ρ（PM_2.5）有扩散作用,对ρ（O₃）有增加作用.海陆风对沿海ρ（PM_2.5）扩散作用最为明显,致使冬、秋两季ρ（PM_2.5）分别下降20.2%和7.9%;对城郊ρ（O₃）增加作用最为明显,致使秋、夏两季ρ（O₃）分别升高39.8%和16.2%.④个例研究表明,海风向内陆推进过程中垂直方向最高可达1 000 m,受海风影响天津市ρ（PM_2.5）下降,陆风使得ρ（PM_2.5）小幅上升,海陆风总体起扩散作用;海陆风使天津市ρ（O₃）日变化出现3个峰值,日均值明显增大,其中,城郊增幅（68.2%）最大.研究显示,海陆风对天津市ρ（PM_2.5）有扩散的作用,但会增高ρ（O₃）.      

基于无人机的大气细颗粒物与臭氧污染探测与溯源研究进展

近年来,中国大气细颗粒物(PM_2.5)污染的治理已取得阶段性成效,但臭氧(O₃)污染快速上升,实现PM_2.5和O₃协同控制的基础与关键是针对大气污染物的精细化探测和污染溯源.随着无人机技术和传感器技术的迅速发展,基于无人机平台的大气污染探测可以有效获得近地层的PM_2.5和O₃结构特征,并结合计算机算法对大气污染事件进行精准溯源,具有高时效性、高灵活性和高时空分辨率的特征,有助于研究人员了解区域污染物的分布、变化以及来源,为大气复合污染的协同控制提供科学依据.通过回顾传统的大气污染探测方法,总结了污染探测领域常用的无人机飞行平台类型和探测仪器,归纳了基于无人机的PM_2.5和O₃污染探测应用与相关溯源算法,并展望了无人机大气探测的未来研究方向.     

成都市大气水汽与空气质量关系的研究

为深入分析大气水汽对空气质量的影响,基于2016年成都温江国家气候观象台的气象观测资料和成都市环境监测中心的环境空气质量指数(AQI),首先利用地面气象要素估算出逐时的大气可降水量(PWV),继而结合空气质量指数资料研究了成都地区降水、静稳天气、太阳辐射强度等气象条件对空气质量及其与大气水汽关系的影响.结果表明:在降水条件下,臭氧(O_3)浓度随着PWV的增大而显著减小,PWV与PM_(2.5)、PM_(10)浓度的正相关系数减小,其中对PWV与PM_(10)浓度的相关性影响最大,相关系数减小47.62%.PWV与O_3的负相关系数在春季增大、夏季减小;PWV与PM_(2.5)的正相关系数在秋、冬季减小.当天气处于高静稳指数时,PWV变化对污染物浓度变化的影响更为显著.不同太阳辐射强度下,PWV与O_3的相关性也不同,随着太阳辐射增强,PWV与PM_(2.5)、PM_(10)的相关性从正相关转变为负相关.