南京北郊地区气溶胶光学性质的四季观测研究
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1.南京信息工程大学环境科学与工程学院;2.商丘市气象局

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国家自然科学基金项目(面上项目,重点项目,重大项目)


A four-season field campaign study of aerosol optical properties in northern suburbs of Nanjing, China
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1.School of Environmental Science and Engineering,Nanjing University of Information Science and Technology;2.Shangqiu Meteorological Administration

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The National Natural Science Foundation of China (General Program, Key Program, Major Research Plan)

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    摘要:

    本研究于2017年12月—2018年11月进行了针对南京北郊地区气溶胶光学性质研究的外场观测。观测期间气溶胶吸收系数和散射系数由高到低分别为冬季、春季、秋季、夏季,日变化呈双峰型,吸收系数早高峰时间夏季早冬季晚,这是由于不同季节边界层高度和人类生产活动时间发生变化导致的。夏秋两季的平均AAE较高,表明棕碳对气溶胶吸收的贡献较为显著,而春冬两季以黑碳吸收为主。SAE春冬季节高于夏秋季节,气溶胶均以细模态为主,春冬季节气溶胶粒径更小。气溶胶光学性质受气象条件和化学组分的影响。受西北季风的影响,污染物的传输使得秋冬季节西北风时气溶胶消光系数存在高值。春夏季节时东风、东南风方向的本地污染源随风扩散到观测点,导致气溶胶消光系数存在高值。秋冬季节在低风速和高风速时气溶胶消光系数均较高,可能是由于低风速时扩散条件较差造成污染物聚积,而高风速时存在污染物的远距离传输。当来自内陆的气团传输到观测点时,观测地点气溶胶消光系数迅速增加,当来自海上的气团传输到观测点时,观测地点气溶胶消光系数降低。当相对湿度小于90%时,气溶胶消光系数与能见度呈反比,而当相对湿度大于90%时,能见度普遍小于10km,且与消光系数关系不大。春冬季节PM2.5组分中水溶性离子主要为二次源离子,且气溶胶消光系数与硝酸根离子的相关性高于硫酸根离子的相关性,影响气溶胶消光系数的污染物主要来自交通源。与此相反,夏秋季节影响气溶胶消光系数的污染物主要来自煤炭燃烧等固定源。棕碳对吸收系数的贡献夏季大于秋季,可能是由于秋季黑碳排放增加使其吸光贡献增加,棕碳吸光贡献相对减少。

    Abstract:

    In this study, a four-season field campaign was conducted from December 2017 to November 2018 for the study of aerosol optical properties in the northern suburbs of Nanjing. The aerosol absorption and scattering coefficients during the observation period were from high to low in winter, spring, fall, and summer, respectively, with bimodal daily variations, and the early peak time of absorption coefficients was early in summer and late in winter, which was due to the changes in the boundary layer heights and the timing of human production activities in different seasons. The average AAE was higher in summer and fall, indicating that brown carbon contributed more significantly to aerosol uptake, while black carbon uptake dominated in spring and winter.SAE was higher in spring and winter than in summer and fall, and both aerosols were dominated by fine modes, with smaller aerosol particle sizes in spring and winter. Aerosol optical properties are influenced by meteorological conditions and chemical components. The transport of pollutants under the influence of the northwest monsoon leads to high values of aerosol extinction coefficients during the fall and winter seasons when the wind is from the northwest. Local pollutants in the direction of east and southeast winds spread to the observation site with wind in spring and summer seasons, resulting in high values of aerosol extinction coefficients. The high aerosol extinction coefficients at both low and high wind speeds during the fall and winter seasons may be attributed to the accumulation of pollutants due to poor diffusion conditions at low wind speeds and the long-range transport of pollutants at high wind speeds. Aerosol extinction coefficients at the observation sites increase rapidly when air masses from inland are transported to the sites, and decrease when air masses from the sea are transported to the sites. When the relative humidity is less than 90%, the aerosol extinction coefficient is inversely proportional to the visibility, while when the relative humidity is more than 90%, the visibility is generally less than 10km, and the relationship with the extinction coefficient is not significant. The water-soluble ions in the PM2.5 components in the spring and winter seasons are mainly secondary source ions, and the correlation between aerosol extinction coefficients and nitrate ions is higher than that of sulfate ions, and pollutants affecting the aerosol extinction coefficients mainly come from transportation sources. In contrast, pollutants affecting aerosol extinction coefficients in summer and fall were mainly from stationary sources such as coal combustion. The contribution of brown carbon to the absorption coefficients was greater in summer than in fall, probably due to the increase in black carbon emissions in fall, which increased its light absorption contribution, and the relative decrease in the light absorption contribution of brown carbon.

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王 兴,许天峰,马 嫣,郑军.南京北郊地区气溶胶光学性质的四季观测研究[J].南京信息工程大学学报,,():

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  • 收稿日期:2023-11-10
  • 最后修改日期:2024-01-19
  • 录用日期:2024-01-22
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