Abstract
Abstract. Atmospheric aerosol particles are known to have detrimental effects on human health and climate. Black carbon is an important constituent of atmospheric aerosol particulate matter (PM), emitted from incomplete combustion. Source apportionment of BC is very important, to evaluate the influence of different sources. The high-resolution soot particle aerosol mass spectrometer (HR-SP-AMS) instrument uses a laser vaporiser, which allows the real-time detection and characterisation of refractory black carbon (rBC) and its internally mixed particles such as metals, coating species, and rBC subcomponents in the form of HOA + fullerene. In this case study, the soot data were collected by using HR-SP-AMS during Guy Fawkes Night on 5 November 2014. Positive matrix factorisation was applied to positively discriminate between different wood-burning and bonfire sources for the first time, which no existing black carbon source apportionment technique is currently able to do. Along with this, the use of the fullerene signals in differentiating between soot sources and the use of metals as a tracer for fireworks has also been investigated, which did not significantly contribute to the rBC concentrations. The addition of fullerene signals and successful positive matrix factorisation (PMF) application to HR-SP-AMS data apportioned rBC into more than two sources. These bonfire sources are HOA + fullerene, biomass burning organic aerosol, more oxidised oxygenated organic aerosol (MO-OOA), and non-bonfire sources such as hydrocarbon-like OA and domestic burning. The result of correlation analysis between HR-SP-AMS data and previously published Aethalometer, MAAP, and CIMS data provides an effective way of gaining insights into the relationships between the variables and provide a quantitative estimate of the source contributions to the BC budget during this period. This research study is an important demonstration of using HR-SP-AMS for the purpose of BC source apportionment.
Highlights
Aerosol particles in the atmosphere are known to have very harmful effects on the air quality, human health, and climate (Highwood and Kinnersley, 2006)
The current study aims to develop the soot particle aerosol mass spectrometer (SP-aerosol mass spectrometer (AMS)) as a source apportionment tool, which will subsequently improve our understanding of the sources of atmospheric soot
The firework tracer Sr has shown some correlation with primary particulate organic oxide of nitrogen (pPON) and biomass burning OA (BBOA), but their peaks occurred at slightly different times
Summary
Aerosol particles in the atmosphere are known to have very harmful effects on the air quality, human health, and climate (Highwood and Kinnersley, 2006). An important component of atmospheric aerosol particles is black carbon (BC), i.e. soot, which has extremely detrimental impacts on human health and air quality (Janssen and WHO Joint, 2012). BC’s main emission source is through the incomplete combustion of fossil fuel and biomass. Open biomass burning, power generation sources, and residential heating (Bond et al, 2011; Cooke et al, 1999; US EPA, 2012). Z. Bibi et al.: A new approach to discriminate different black carbon sources emission or through gas-to-particle conversion processes in the atmosphere
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