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挥发性有机化合物(VOC)源解析:监测特征如何影响正定矩阵因子分解(PMF)结果。

VOC source apportionment: How monitoring characteristics influence positive matrix factorization (PMF) solutions.

作者信息

Frischmon Caroline, Hannigan Michael

机构信息

Department of Mechanical Engineering, University of Colorado Boulder, Boulder, CO, 80309, USA.

出版信息

Atmos Environ X. 2024 Feb;21. doi: 10.1016/j.aeaoa.2023.100230. Epub 2023 Dec 12.

DOI:10.1016/j.aeaoa.2023.100230
PMID:38577261
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10993988/
Abstract

Positive matrix factorization (PMF) can be used to develop more targeted air quality mitigation strategies by identifying major sources of a pollutant in an area. This technique is dependent, however, on the ability of PMF to resolve factors that accurately represent all sources of that pollutant in an area. We investigated how the accuracy of PMF solutions might be influenced by monitoring data characteristics, such as temporal resolution, monitoring location, and species composition, to better inform the use of PMF in VOC mitigation strategies. We applied PMF to five VOC monitoring programs collected within a four-year period in Colorado and found generally consistent factors, which we identified as oil extraction, processing, and evaporation; natural gas; vehicle exhaust; and liquid gasoline/short-lived oil and gas. The main determinant influencing whether or not a dataset resolved each of these sources was whether the dataset had a comprehensive list of VOC species covering key species of each source. Pollution spikes were not well-modeled in any of the solutions. Hyperlocal and volatile chemical product factors expected to be resolved in the industrialized, urban location were also missing, highlighting three limitations of PMF analysis. Wind direction dependence and diurnal trends aided in source identification, suggesting that high-time resolution data is important for developing actionable PMF results. Based on these findings, we recommend that air monitoring for PMF-informed VOC mitigation efforts include high temporal resolution and a comprehensive array of VOC species.

摘要

正定矩阵因子分解(PMF)可用于通过识别某一区域污染物的主要来源来制定更具针对性的空气质量缓解策略。然而,该技术取决于PMF分辨那些能准确代表该区域内该污染物所有来源的因子的能力。我们研究了监测数据特征(如时间分辨率、监测地点和物种组成)如何影响PMF解决方案的准确性,以便更好地指导PMF在挥发性有机化合物(VOC)缓解策略中的应用。我们将PMF应用于科罗拉多州四年内收集的五个VOC监测项目,发现了总体一致的因子,我们将其确定为石油开采、加工和蒸发;天然气;汽车尾气;以及液态汽油/短期油气。影响数据集是否能分辨出这些来源的主要决定因素是该数据集是否有涵盖每个来源关键物种的VOC物种综合清单。在任何解决方案中,污染峰值都没有得到很好的模拟。预计在工业化城市地区能分辨出的超本地和挥发性化学产品因子也缺失,这突出了PMF分析的三个局限性。风向依赖性和日变化趋势有助于源识别,这表明高时间分辨率数据对于得出可采取行动的PMF结果很重要。基于这些发现,我们建议,为基于PMF的VOC缓解措施进行的空气监测应包括高时间分辨率和一系列全面的VOC物种。

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