SEASONAL CHARACTERISTIC OF WATER-SOLUBLE IONS OF PM1 IN SOUTHWEST SUBURB OF CHENGDU
-
摘要: 为研究成都市西南郊区PM1中水溶性离子的季节特征及其来源,于2019年1,4,7,10月采集PM1样品并对其中的8种水溶性离子(NO3-、SO42-、NH4+、Ca2+、Cl-、K+、Na+和Mg2+)进行分析,开展PM1和水溶性离子质量浓度及其相关关系的对比分析。结果表明:2019年,成都市西南郊区PM1和水溶性离子年均总浓度分别为(30.1±12.5),(8.5±6.2)μg/m3,各离子浓度高低顺序为NO3->SO42->NH4+>K+>Ca2+>Cl->Na+>Mg2+;二次离子SNA(SO42-、NO3-、NH4+)占总水溶性离子比例达到90.0%以上,其在PM1中占比的季节差异明显,冬季(35.0%)>春季(23.6%)>秋季(22.0%)>夏季(17.5%)。春、夏季NO3-/SO42-分别为0.9和0.6,而秋、冬季NO3-/SO42-分别为1.2和2.1,说明春夏季固定源对PM1贡献更大,秋冬季移动源对PM1的贡献更加显著。受来源和气象条件影响,SOR和NOR年均值分别为0.37和0.04,表明观测期间SO2的二次生成率更为突出。主成分分析结果显示,成都市西南郊区PM1中水溶性离子的主要来源有二次无机源、燃煤、生物质燃烧和扬尘。Abstract: To investigate the seasonal characteristics and sources of water-soluble ions in PM1 in the southwest suburb of Chengdu, samples were collected during typical seasonal months(January, April, July and October)of 2019, and 8 main kinds of water-soluble ions, including NO3-, SO42-, NH4+, Ca2+, Cl-, K+, Na+, Mg2+ in the samples were detected, and finally the mass concentrations and correlation among PM1 and its water-soluble ions components were analyzed in this research. The result showed that the annual average concentrations of PM1 and total water-soluble ions were(30.1±12.5) μg/m3 and(8.5±6.2) μg/m3, respectively. Concentrations of ions were, from more to less, in an order of NO3->SO42->NH4+>K+>Ca2+>Cl->Na+>Mg2+. Secondary ions(SNA) contributed as high as 90.0% of the total water-soluble ions, and their contributions to PM1 were different between seasons, which were 35.0%, 23.6%, 22.0% and 17.5% in winter, spring, autumn and summer, respectively. The ratios of NO3-/SO42- were 0.9 and 0.6 in spring and summer, and 1.2 and 2.1 in autumn and winter, which revealed that the vehicle sources played an important role in the formation of PM1 in autumn and winter. The mean values of sulfur oxidation rate(SOR) and nitrogen oxidation rate(NOR) were 0.37 and 0.04, due to the variations in sources and meteorological conditions, respectively, indicating that there was a higher secondary aerosol transformation rate of sulfur. The results of principle component analysis indicated that the secondary inorganic sources, coal combustion, biomass burning and dust were the main sources of the water-soluble ions during the sampling periods.
-
Key words:
- Chengdu /
- PM1 /
- water-soluble ions /
- seasonal characteristic /
- source
-
[1] LI Y Y,CHANG M,DING S S,et al.Monitoring and source apportionment of trace elements in PM2.5:implications for local air quality management[J].Journal of Environmental Management,2017,196:16-25. [2] HUANG H T,GAO L R,XIA D,et al.Characterization of short- and medium-chain chlorinated paraffifins in outdoor/indoor PM10/PM2.5/PM1.0 in Beijing,China[J].Environmental Pollution,2017,225:674-680. [3] ZHOU Y,CHENG S Y,CHEN D S,et al.Temporal and spatial characteristics of ambient air quality in Beijing,China[J].Aerosol and Air Quality Research,2015,15:1868-1880. [4] DING X X,KONG L D,DU C T,et al.Long-range and regional transported size-resolved atmospheric aerosols during summertime in urban Shanghai[J].Science of Total Environment,2017,583:334-343. [5] YANG B Y,GUO Y,BLOOM M S,et al.Ambient PM1 air pollution,blood pressure,and hypertension:insights from the 33 communities Chinese Health Study[J].Environmental Research,2019,170:252-259. [6] LIN H L,TAO J,DU Y D,et al.Particle size and chemical constituents of ambient particulate pollution associated with cardiovascular mortality in Guangzhou,China[J].Environmental Pollution,2016,208(Pt B):758-766. [7] YANG M,CHU C,BLOOM M S,et al.Is smaller worse? New insights about associations of PM1 and respiratory health in children and adolescents[J].Environment International,2018,120:516-524. [8] WANG H L,ZHU B,SHEN L J,et al.Water-soluble ions in atmospheric aerosols measures in five sites in the Yangtze River Delta,China:size-fractionated,seasonal variation and sources[J].Atmospheric Environment,2015,123:370-379. [9] XU L L,DUAN F K,HE K B,et al.Characteristics of the secondary water-soluble ions in a typical autumn haze in Beijing[J].Environmental Pollution,2017,227:296-305. [10] ROGULA-KOZOWSKA W,MAJEWSKI G,WIDZIEWICZ K,et al.Seasonal variations of PM1-bound water concentration in urban areas in Poland[J].Atmospheric Pollution Research,2019,10(1):267-273. [11] PADOAN S,ZAPPI A,ADAM T,et al.Organic molecular markers and source contributions in a polluted municipality of north-east Italy:extended PCA-PMF statistical approach[J].Environmental Research,2020,186:109587. [12] ARUB Z,SINGH G,HABIB G,et al.Highly significant impact of mineral dust on aerosol hygroscopicity at New Delhi[J].Atmospheric Environment,2021,254:118375. [13] 林瑜,叶芝祥,杨怀金,等.成都市中心城区大气PM1的污染特征及来源解析[J].中国环境科学,2017,37(9):3220-3226. [14] LANG J L,LI S Y,CHENG S Y,et al.Chemical characteristics and sources of submicron particles in a city with heavy pollution in China[J].Atmosphere,2018,9(10):388. [15] ZHANG Y Y,LANG J L,CHENG S Y,et al.Chemical composition and sources of PM1 and PM2.5 in Beijing in autumn[J].Science of Total Environment,2018,630:72-82. [16] LI Z R,NIE D Y,CHEN M D,et al.Seasonal variation of oxidative potential of water-soluble components in PM2.5 and PM1 in the Yangtze River Delta,China[J].Air Quality Atmosphere & Health,2021,14:1825-1836. [17] XIA Y J,TAO J,ZHANG L M,et al.Impact of size distributions of major chemical components in fine particles on light extinction in urban Guangzhou[J].Science of the Total Environment,2017,587/588:240-247. [18] FENG X,WEI S,WANG S.Temperature inversions in the atmospheric boundary layer and lower troposphere over the Sichuan Basin,China:climatology and impacts on air pollution[J].Science of the Total Environment,2020,726:138579. [19] GUO M T,CAI X H,SONG Y.Characteristics of low wind speed meteorology in China[J].Acta Scientiarum Nauralium Universitatis Pekinsis,2016,52(2):219-226. [20] LIAO T T,GUI K,JIANG W T,et al.Air stagnation and its impact on air quality during winter in Sichuan and Chongqing,southwestern China[J].The Science of the Total Environment,2018,635:576. [21] CHENG X,HUANG Y,ZHANG S P,et al.Characteristics,sources,and health risk assessment of trace elements in PM10 at an urban site in Chengdu,Southwest China[J].Aerosol and Air Quality Research,2017,18(2):357-370. [22] WANG J J,HUANG Y,LI T,et al.Annual Characteristics,source analysis of PM1 bound potentially harmful elements in the eastern district of chengdu,China[J].Archives of Environmental Contamination and Toxicology,2020,79:177-183. [23] ZHAO S P,YIN D Y,YU Y,et al.PM1 chemical composition and light absorption properties in urban and rural areas within Sichuan Basin,southwest China[J].Environment Pollution,2021,280:116970. [24] WANG Y S,YAO L,WANG L L,et al.Mechanism for the formation of the January 2013 heavy haze pollution episode over central and eastern China[J].Science China Earth Sciences,2014,57(1):14-25. [25] 樊啸辰,郎建垒,程水源,等.北京市大气环境PM2.5和PM1及其碳质组分季节变化特征及来源分析[J].环境科学,2018,10(10):4430-4438. [26] QIAO T,ZHAO M F,XIU G L,et al.Seasonal variations of water soluble composition (WSOC,Hulis and WSIIs) in PM1 and its implications on haze pollution in urban Shanghai,China[J].Atmospheric Environment,2015,123:306-314. [27] TAO J,SHEN Z X,ZHU C S,et al.Seasonal variations and chemical characteristics of sub-micrometer particles (PM1) in Guangzhou,China[J].Atmospheric Research,2012,118:222-231. [28] 毛红梅,张凯山,第宝锋,等.成都市大气污染物排放清单高分辨率的时空分配[J].环境科学学报,2017,37(1):23-33. [29] ZHANG R Y,WANG G H,GUO S,et al.Formation of urban fine particulate matter[J].Chemical Reviews,2015,115(10):3803-3855. [30] 林雅洁.我国PM2.5中可溶性无机离子组分的来源及特点[J].广东化工,2017,44(8):136-138. [31] SHEN Z X,ARIMOTO R,CAO J J,et al.Seasonal variations and evidence for the effectiveness of pollution controls on water-soluble inorganic species in total suspended particulates and fine particulate matter from Xi’an,China[J].Journal of Air & Waste Management Assosiation,2008,58:1560-1570. [32] RUSSELL A G,MCRAE G J,CASS G R.Mathematical modeling of the formation and transport of ammonium nitrate aerosol[J].Atmospheric Environment[J].1983,17(5):949-964. [33] ZHAO P S,DONG F,HE D,et al.Characteristics of concentrations and chemical compositions for PM2.5 in the region of Beijing,Tianjin,and Hebei,China[J].Atmospheric Chemistry and Physics,2013,13(9):4631-4644. [34] WANG H B,TIAN M,LI X H,et al.Chemical Composition and Light Extinction Contribution of PM2.5 in Urban Beijing for a 1-Year Period[J].Aerosol and Air Quality Research,2015,15:2200-2211. [35] ZHANG J K,CHENG M T,JI D S,et al.Characterization of sub-micron particles during biomass burning and coal combustion period in Beijing,China[J].Science of the Total Environment,2016,562:812-821. [36] WANG Y,ZHANG G S,TANG A H,et al.The ion chemistry and the source of PM2.5 aerosol in Beijing[J].Atmospheric Environment,2005,39(21):3771-3784. [37] YAO X H,CHAN C K,FANG M,et al.The water-soluble ionic composition of PM2.5 in Shanghai and Beijing,China[J].Atmospheric Environment,2002,36(26):4223-4234. [38] 张丹,翟崇治,周志恩,等.重庆市主城区不同粒径颗粒物水溶性无机组分特征[J].环境科学研究,2012,25(10):1099-1106. [39] CLEGG S L,BRIMBLECOMBE P,WEXLER A S.Thermodynamic model of the system H+-NH4+-SO42--NO3--H2O at tropospheric temperatures[J].The Journal of Physical Chemistry A,1998,102(12):2137-2154. [40] GENG N B,WANG J,XU Y F,et al.PM2.5 in an industrial district of Zhengzhou,China:chemical composition and source apportionment[J].Particuology,2013,11(1):99-109. [41] 孙有昌,姜楠,王申博,等.安阳市大气PM2.5中水溶性离子季节特征及来源解析[J].环境科学,2020,41(1):77-83. [42] HAN Y M,DU P X,CAO J J,et al.Multivariate analysis of heavy metal contamination in urban dusts of Xi’an,Central China[J].Science of the Total Environment,2006,355:176-186. [43] 闫广轩,张靖雯,雷豪杰,等.郑州市大气细颗粒物中水溶性离子季节性变化特征及其源解析[J].环境科学,2019,40(4):1545-1552.
点击查看大图
计量
- 文章访问数: 225
- HTML全文浏览量: 33
- PDF下载量: 25
- 被引次数: 0