A case study in the wintertime Vaal Triangle Air-Shed Priority Area on the utility of the nitrogen stable isotopic composition of aerosol nitrate to identify NOx sources

Q3 Environmental Science

Clean Air Journal Pub Date : 2022-06-24 DOI:10.17159/caj/2022/32/1.12505

K. Altieri, Jessica Burger, B. Language, S. Piketh

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引用次数: 1

Abstract

In South Africa, the Highveld region and the Johannesburg-Pretoria megacity are known as global NOx (NOx = NO + NO2) “hotspots” identified by satellite-based instruments. The ultimate sink for atmospheric NOx is conversion to aerosol nitrate. However, measurements of aerosol nitrate concentrations do not provide information on which NOx sources served as nitrate precursors at that location. This complicates efforts to reduce concentrations of particulate matter (PM) in these air quality priority areas. Here, we measured the nitrogen stable isotopic composition of nitrate from daily wintertime collections of coarse mode PM2.5-10 (PM ≤ 10 and >2.5 µm in diameter) at three air quality monitoring stations located in the Vaal Triangle Air-Shed Priority Area (VTAPA). The overall aim of this case study was to evaluate the use of the distinct stable isotopic signatures of various NOx sources to identify their relative contribution to aerosol nitrate across the Highveld. The nitrogen isotopic ratios of aerosol nitrate were similar across the three sites, with greater day-to-day variability than site to site variability. Air mass history was the main driver of the variability in the nitrogen isotopic ratios of aerosol nitrate, with significantly higher isotopic ratios observed for air masses originating from the southwest. Using an isotope mixing model we determined that NOx from coal-burning is the dominant contributor to aerosol nitrate (66%), followed by biomass burning (16%), vehicles (12%), and soil emissions (6%).

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以冬季val三角风棚优先区为例，研究利用气溶胶硝酸盐的氮稳定同位素组成来识别氮氧化物来源

在南非，Highveld地区和约翰内斯堡-比勒陀利亚特大城市被卫星仪器确定为全球氮氧化物(NOx = NO + NO2)“热点”。大气中氮氧化物的最终汇是转化为气溶胶硝酸盐。然而，对气溶胶硝酸盐浓度的测量并不能提供有关哪些氮氧化物来源在该地点充当硝酸盐前体的信息。这使得在这些空气质量重点地区降低颗粒物(PM)浓度的努力变得复杂。在这里，我们测量了位于瓦尔三角空气棚优先区(VTAPA)的三个空气质量监测站冬季日常收集的粗态PM2.5-10 (PM≤10和>直径2.5µm)中硝酸盐的氮稳定同位素组成。本案例研究的总体目的是评估各种氮氧化物来源的不同稳定同位素特征的使用情况，以确定它们对整个高原气溶胶硝酸盐的相对贡献。气溶胶硝酸盐的氮同位素比率在三个站点之间相似，其日变异性大于站点间变异性。气团历史是气溶胶硝酸盐氮同位素比率变化的主要驱动因素，来自西南的气团观测到的同位素比率明显较高。使用同位素混合模型，我们确定燃煤产生的氮氧化物是气溶胶硝酸盐的主要来源(66%)，其次是生物质燃烧(16%)、车辆(12%)和土壤排放(6%)。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Clean Air Journal Environmental Science-Management, Monitoring, Policy and Law

CiteScore

1.80

自引率

0.00%

发文量

审稿时长

8 weeks

期刊介绍： Clean Air Journal is the official publication of the National Association for Clean Air, a not-for-profit organisation. Clean Air Journal is a peer-reviewed journal for those interested in air quality, air quality management, and the impacts of air pollution relevant to Africa. The focus of the journal includes, but is not limited to: Impacts of human activities and natural processes on ambient air quality Air quality and climate change linkages Air pollution mitigation technologies and applications Matters of public policy regarding air quality management Measurement and analysis of ambient and indoor air pollution Atmospheric modelling application and development Atmospheric emissions Other topics on atmospheric physics or chemistry with particular relevance to Africa The scope of the journal is broad, but the core theme of the journal is air quality in Africa.