| 夏秋季宁波市气态元素汞(GEM)污染特征及潜在源区贡献分析 |
| 摘要点击 1480 全文点击 610 投稿时间:2019-06-04 修订日期:2019-08-01 |
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| 中文关键词 气态元素汞(GEM) 光化学氧化 空气污染物 相关性分析 潜在源贡献分析(PSCF) |
| 英文关键词 gaseous elemental mercury (GEM) atmospheric photochemical oxidation atmospheric pollutants correlation analysis potential source contribution function analysis (PSCF) |
| 作者 | 单位 | E-mail | | 易辉 | 中国科学院城市环境研究所城市环境与健康重点实验室, 厦门 361021
中国科学院大学, 北京 100049
中国科学院区域大气环境研究卓越创新中心, 厦门 361021
中国科学院宁波城市环境观测研究站, 宁波 315800 | hyi@iue.ac.cn | | 林佳梅 | 中国科学院城市环境研究所城市环境与健康重点实验室, 厦门 361021
中国科学院大学, 北京 100049
中国科学院区域大气环境研究卓越创新中心, 厦门 361021
中国科学院宁波城市环境观测研究站, 宁波 315800 | | | 蔡秋亮 | 中国科学院城市环境研究所城市环境与健康重点实验室, 厦门 361021
中国科学院大学, 北京 100049
中国科学院区域大气环境研究卓越创新中心, 厦门 361021
中国科学院宁波城市环境观测研究站, 宁波 315800 | | | 王克强 | 中国科学院城市环境研究所城市环境与健康重点实验室, 厦门 361021
中国科学院大学, 北京 100049
中国科学院区域大气环境研究卓越创新中心, 厦门 361021
中国科学院宁波城市环境观测研究站, 宁波 315800 | | | 陈进生 | 中国科学院城市环境研究所城市环境与健康重点实验室, 厦门 361021
中国科学院区域大气环境研究卓越创新中心, 厦门 361021 | | | 佟磊 | 中国科学院城市环境研究所城市环境与健康重点实验室, 厦门 361021
中国科学院区域大气环境研究卓越创新中心, 厦门 361021
中国科学院宁波城市环境观测研究站, 宁波 315800 | | | 李建荣 | 中国科学院城市环境研究所城市环境与健康重点实验室, 厦门 361021
中国科学院宁波城市环境观测研究站, 宁波 315800 | | | 肖航 | 中国科学院城市环境研究所城市环境与健康重点实验室, 厦门 361021
中国科学院区域大气环境研究卓越创新中心, 厦门 361021
中国科学院宁波城市环境观测研究站, 宁波 315800 | hxiao@iue.ac.cn |
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| 中文摘要 |
| 气态元素汞(gaseous elemental mercury,GEM)是普遍存在于大气中的对生物体有害的重金属元素,其化学性质稳定,在大气中停留时间长,可随气团长距离输送,属于全球性污染物.本研究于2017年夏秋季对宁波市大气GEM、常规污染物和气象参数进行综合观测,研究沿海地区GEM受人为源和自然源共同作用下的迁移转化规律及潜在源贡献来源.结果表明:①观测期间大气GEM的平均质量浓度为(2.32±0.90)ng·m-3,变化范围为0.97~10.95 ng·m-3,且夏季低于秋季.② GEM、O3和GOM在夏季、秋季、晴天和阴雨天的日内浓度变化表明,高浓度的O3和强烈的光照可加速GEM发生光化学反应,GEM在晴天的光化学氧化强度高于阴雨天.③相关性分析表明,GEM与PM2.5(R=0.65,P<0.01)、PM10(R=0.47,P<0.01)、NO2(R=0.46,P<0.01)和CO(R=0.57,P<0.01)呈显著正相关关系,其来源与化石燃料等物质燃烧有关.④ O3等光化学氧化剂的浓度、GEM在颗粒物上的气粒分配及PM2.5、水汽和NO2的消光效应,可对GEM光化学氧化速率产生重要影响.⑤潜在源贡献分析(potential source contribution function analysis,PSCF)结果表明,夏季浙江省北部(包含宁波市)、西北部,安徽省南部和江西省大部分地区构成一个三角形区域是NBUEORS大气GEM的潜在源贡献区域,且本地源、区域源和长距离源输送对GEM污染均具有重要影响.秋季的潜在源贡献区域主要为浙江省北部区域,范围小于夏季.GEM主要来自本地源和区域源输送影响.因此,针对大气GEM污染的控制,需要跨省的区域联防联控,综合治理,方可有效减轻大气汞的污染. |
| 英文摘要 |
| Gaseous elemental mercury (GEM) is commonly known as a hazardous heavy metal in the atmosphere and is harmful to living organisms. GEM is chemically stable and has a long residence time in the atmosphere; hence, it can be transported over long distances with air masses and is regarded as a global pollutant. We study the transportation and transformation mechanisms of GEM and its potential anthropogenic and natural contribution sources. GEM, conventional atmospheric pollutants, and meteorological parameters were monitored at a coastal site in Ningbo during the summer and autumn of 2017. The results were as follows. ① The concentrations of GEM ranged from 0.97-10.95 ng·m-3 and the mean and standard deviation (SD) were (2.32±0.90) ng·m-3, whereby the mean summer concentration was lower than the mean autumn concentration. ② The diurnal variations of GEM, ozone (O3), and gaseous oxidized mercury (GOM) during summer/autumn and sunny/rainy days suggest that higher levels of O3 and that strong solar radiation accounted for the rapid photochemical oxidation of GEM. The intensity of oxidation on sunny days was higher than that on rainy days. ③ Correlation analysis showed that GEM was significantly positively correlated with PM2.5 (R=0.65, P<0.01), PM10 (R=0.47, P<0.01), NO2 (R=0.46, P<0.01), and CO (R=0.57, P<0.01). Local and regional sources of GEM were mainly related to fossil fuel combustion. ④ The photochemical oxidation rate of GEM was influenced by the concentrations of oxidants (e.g., O3), gas-particle partitioning between GEM and particles, and light extinction effects of PM2.5, water vapor, and NO2. ⑤ Potential source contribution analysis (PSCF) indicated that the northwestern Zhejiang Province (including Ningbo City), the southern Anhui Province, and most of Jiangxi Province constitute a triangular area that is a potential source contribution to NBUEORS atmospheric GEM pollution during the summer. Local, regional, and long-range sources all had strong impacts on GEM pollution. During the autumn, the potential sources were mainly in the northern Zhejiang Province, and the source was smaller than that during the summer. GEM pollution during the autumn was mainly influenced by local and regional sources. Therefore, the control of atmospheric GEM pollution in the Yangtze River delta should apply inter-regional prevention and comprehensive control strategies in order to reduce atmospheric mercury pollution. |
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