冬末北极气溶胶有机和无机离子的地球化学特征

Shao-Meng Li , John W. Winchester
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引用次数: 62

摘要

为了检验北极对流层中可能的自然和人为气溶胶离子成分,我们测量了阿拉斯加州巴罗地区冬末北极气溶胶中12种有机和无机离子的浓度,并将其作为分离的粗组分和细组分取样。无机离子浓度与以前北极报告的数据相似。有机阴离子甲烷磺酸盐(MSA)总体为粗+细,平均为0.12±0.02 nmol m−3。发现了高含量的甲酸盐(Fo−)和乙酸盐(Ac−)以及微量的丙酸盐(Pp−)和丙酮酸盐(Py−),它们总共占气溶胶总质量的20%。总浓度为(Fo−)5.3±0.7,(Ac−)12.4±2.2,(Pp−)0.3±0.1,(Py−)0.1±0.04。羧酸阴离子之间的内在关系表明自然植被的排放。由于冬季缺乏本地来源,这些有机阴离子很可能来自低纬度地区,在寒冷的北极以酸性蒸汽的形式与气态NH3凝聚成气溶胶。通过绝对主成分分析(APCA),发现了4种气溶胶类型,并以69个12 h样品的粗、细气溶胶组分中的7个主成分为证。最突出的一类是被污染的海盐,显然是在清除燃烧产物后运到北极的。第二种含有羧酸阴离子,例如可能是低纬度地区自然来源的有机酸蒸汽与NH3共缩合产生的。第三种是海洋气溶胶组分,含有大部分MSA、Br−和NO−3,以及少量的羧酸阴离子和一些海盐,可能是前体气相氧化的产物集合。最后,发现了一种细小的非海盐硫酸盐(nssSO2−4)成分,可能来自空气中的SO2转化。大多数组分的被测离子具有良好的电荷平衡,阴离子/正离子比接近一致。这些比值反映了组分中近似的酸碱中和作用,表明了具有较长大气停留时间的老化气溶胶系统。将粗组分和细组分结合起来看,大约10%的羧酸阴离子与气溶胶类型1中的污染物有关。类型2占80%的Fo−和60%的Ac−。类型3占18%的Fo−和10%的Ac−。因此,羧酸阴离子似乎大部分是天然的,在2型和3型中有超过90%的Fo -和70%的Ac -。在粗粒气溶胶中,67%的nssSO2−4存在于被污染的海盐中。在细颗粒物中,52%的nssSO2−4是由SO2氧化形成的单独的SO2−4组分。一些nssSO2−4与两个组分的MSA有关,并归因于天然海洋生物源S前体。SO2−4约占测量到的nssSO2−4总量的20%。这些结果表明,天然化合物是北极气溶胶的可测量成分,可占总测量气溶胶质量的60%。在未来的北极雾霾研究中,应同时考虑自然物质和人为物质。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Geochemistry of organic and inorganic ions of late winter arctic aerosols

In order to examine possible natural as well as anthropogenic aerosol ionic components in the Arctic troposphere, we have measured the concentrations of 12 organic and inorganic ions in late winter Arctic aerosols at Barrow, Alaska, sampled as separated coarse and fine fractions. Inorganic ion concentrations are similar to previous data reported from the Arctic. The organic anion methanesulfonate (MSA), in total coarse + fine, averages 0.12 ± 0.02 nmol m−3. High levels of formate (Fo ) and acetate (Ac) and traces of propionate (Pp) and pyruvate (Py) are found, which altogether account for 20% of the total aerosol mass. Total concentrations, as mean ± S.E. nmol m−3, are (Fo) 5.3± 0.7, (Ac) 12.4 ± 2.2, (Pp) 0.3±0.1, and (Py) 0.1 ± 0.04. Internal relationships among the carboxylic acid anions suggest emissions from natural vegetation. Lacking local sources during winter, these organic anions are likely to have come from lower latitudes as acid vapors that condensed with gaseous NH3 into aerosols in the cold Arctic.

Four aerosol types, evidenced by seven principal components in the coarse and fine aerosol fractions of 69 12-h samples, are found by absolute principal component analysis (APCA). The most prominent type is a contaminated sea salt, apparently transported to the Arctic after scavenging combustion products. The second contains carboxylic acid anions, such as could have resulted from co-condensation with NH3 of organic acid vapors from natural sources at lower latitudes. The third is a marine aerosol component containing most of the MSA, Br and NO3, as well as small amounts of carboxylic acid anions and some sea salt, and may be a collection of products from gas phase oxidation of precursors. Finally, a fine non-sea salt sulfate (nssSO2−4) component is found that may have come from SO2 conversion in air. Most components have good charge balance of the measured ions as indicated by anion/cation ratios near unity. The ratios reflect approximate acid-base neutralization in the components and indicate aged aerosol systems with long atmospheric residence times.

Viewing similar components in coarse and fine fractions together, about 10% of the carboxylic acid anions are associated with pollutants in aerosol type 1. Type 2 accounts for 80% of Foand 60% of Ac. Type 3 accounts for 18% of Fo and 10% of Ac. Thus, the carboxylic acid anions appear to be mostly natural, with more than 90% of Fo and 70% of Ac in types 2 and 3. In coarse aerosols viewed separately, 67% of nssSO2−4 is in the contaminated sea salt. In fine aerosols, 52% of nssSO2−4 is in a separate SO2−4 component which may be formed by SO2 oxidation. Some nssSO2−4 is associated with MSA in both fractions and is attributed to natural marine biogenic S precursors. This SO2−4 is about 20% of total measured nssSO2−4. These results show that natural compounds are measurable constituents of Arctic aerosols and can account for 60% of the total measured aerosol mass. In future Arctic haze studies both natural and anthropogenic substances should be considered.

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