中文关键词臭氧时空分布区域多尺度空气质量(CMAQ)模型源解析外来源本地源 英文关键词ozonespatial and temporal distributioncommunity multiscale air quality(CMAQ)modelsource apportionmentnon-local sourceslocal sources

作者	单位	E-mail
王俏丽	浙江大学能源工程学院, 能源清洁利用国家重点实验室, 热能工程研究所, 杭州 310027 浙江大学化学工程与生物工程学院, 生物质化工教育部重点实验室, 工业生态与环境研究所, 杭州 310027	chocowang@zju.edu.cn
董敏丽	浙江大学化学工程与生物工程学院, 生物质化工教育部重点实验室, 工业生态与环境研究所, 杭州 310027
李素静	浙江大学化学工程与生物工程学院, 生物质化工教育部重点实验室, 工业生态与环境研究所, 杭州 310027
吴成志	三捷环境工程咨询(杭州)有限公司, 杭州 310012
王刚	三捷环境工程咨询(杭州)有限公司, 杭州 310012
陈必新	三捷环境工程咨询(杭州)有限公司, 杭州 310012
李伟	浙江大学化学工程与生物工程学院, 生物质化工教育部重点实验室, 工业生态与环境研究所, 杭州 310027	w_li@zju.edu.cn
高翔	浙江大学能源工程学院, 能源清洁利用国家重点实验室, 热能工程研究所, 杭州 310027	xgao1@zju.edu.cn
叶荣民	浙江省舟山海洋生态环境监测站, 舟山 316021

中文摘要 臭氧及其前体物在环境空气中传输和反应过程复杂，本研究利用舟山市国控点2014年的监测数据对臭氧污染时空分布开展了统计分析，并利用CMAQ（community multiscale air quality）模型模拟了舟山市2014年臭氧污染形成，选用ISAM（integrated source apportionment method）源追踪算法计算来源贡献率.结果表明，舟山市春秋季节的臭氧浓度相对较高，浓度高值出现在午后13：00~15：00.普陀站的臭氧平均浓度最高而位于中心城区的临城站最低.臭氧总体浓度不高，但易出现单日浓度高值，其中5月臭氧超标率最高.舟山市本地臭氧形成主要受VOCs浓度控制，而源解析结果表明舟山市全年外来源占总贡献的69.46%.本地源中，工业燃烧源、工艺过程源、道路移动源、非道路移动源的贡献率相差不大，且表现出显著的港口城市特征，船舶源、石化源、储运源分别占总贡献的4.45%和1.01%和1.80%.控制臭氧污染应采取周边区域联防联控的措施，以VOCs排放源为主，不同来源协同调控的措施. 英文摘要 The processes affecting photochemical reactions and regional transport of ozone and its precursors in ambient air are very complicated. In this study, statistical analysis of the spatial and temporal distributions of ozone pollution in Zhoushan was carried out based on monitoring data from state monitoring stations in Zhoushan in 2014. Specifically, ozone formation was simulated by CMAQ (the community multiscale air quality) model, and the source contribution rate was calculated using the Integrated Source Apportionment Method (ISAM) source tracking algorithm. The results showed that ozone pollution was more severe in spring and autumn than in summer and winter, and the highest ozone concentrations mostly appeared during 13:00-15:00 in the afternoon. Putuo Station had the highest ozone concentration while Lincheng Station, located in the downtown area of the city, had the lowest ozone concentration. The overall average ozone concentration was not high; however, peak concentrations that exceeded the standards usually occurred, which occurs most often in May. Local ozone formation in Zhoushan City is controlled by the VOC concentration, and source tracking results showed that non-local sources accounted for 69.46% of the total contribution. Among local emission sources, fuel burning boiler sources, industry process sources, on-road mobile sources, and non-road mobile sources made similar contributions to ozone formation. Moreover, they showed significant characteristics of a port city. The contribution rates from shipping sources, petrochemical sources, and storage and transportation sources were 4.45%, 1.01%, and 1.80%, respectively. In conclusion, control of the ozone pollution in Zhoushan City should be based on simultaneous reduction and coordinated prevention involving multiple sources (VOCs as the main one) both locally and in surrounding areas.

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