Characterisation of sub-micron particle number concentrations and formation events in the western Bushveld Igneous Complex, South Africa

A Hirsikko,S Gagné,A Mirme,M Kulmala,V Vakkari,D Mabaso,S Mirme,L Laakso,P Tiitta,J P Beukes,H Laakso,H E Manninen

doi:10.5194/acp-12-3951-2012

Abstract

Abstract. South Africa holds significant mineral resources, with a substantial fraction of these reserves occurring and being processed in a large geological structure termed the Bushveld Igneous Complex (BIC). The area is also highly populated by informal, semi-formal and formal residential developments. However, knowledge of air quality and research related to the atmosphere is still very limited in the area. In order to investigate the characteristics and processes affecting sub-micron particle number concentrations and formation events, air ion and aerosol particle size distributions and number concentrations, together with meteorological parameters, trace gases and particulate matter (PM) were measured for over two years at Marikana in the heart of the western BIC. The observations showed that trace gas (i.e. SO2, NOx, CO) and black carbon concentrations were relatively high, but in general within the limits of local air quality standards. The area was characterised by very high condensation sink due to background aerosol particles, PM10 and O3 concentration. The results indicated that high amounts of Aitken and accumulation mode particles originated from domestic burning for heating and cooking in the morning and evening, while during daytime SO2-based nucleation followed by the growth by condensation of vapours from industrial, residential and natural sources was the most probable source for large number concentrations of nucleation and Aitken mode particles. Nucleation event day frequency was extremely high, i.e. 86% of the analysed days, which to the knowledge of the authors is the highest frequency ever reported. The air mass back trajectory and wind direction analyses showed that the secondary particle formation was influenced both by local and regional pollution and vapour sources. Therefore, our observation of the annual cycle and magnitude of the particle formation and growth rates during nucleation events were similar to results previously published for a semi-clean savannah site in South Africa.

Highlights

Aerosol particles may affect climate directly by scattering and reflecting radiation, or indirectly via cloud-aerosol interactions (Lohmann and Feichter, 2005; Myhre, 2009; Quaas et al, 2009; Hand and Malm, 2007; IPCC, 2007)
The aims of this work were to investigate the characteristic behaviour of sub-micron particles by investigating ion and particle concentrations, as well as new particle formation based on nucleation event classification, formation and growth rate analyses
The analysis showed that the faster growth rates were observed when Aitken mode particle concentrations were higher

Summary

Introduction

Aerosol particles may affect climate directly by scattering and reflecting radiation, or indirectly via cloud-aerosol interactions (Lohmann and Feichter, 2005; Myhre, 2009; Quaas et al, 2009; Hand and Malm, 2007; IPCC, 2007). Kulmala et al, 2004, 2011), but the number of observations in the developing world is still very limited. There are no previous observations of ultrafine particle number concentrations or size distributions from residential areas in southern Africa. In a relatively clean background savannah area in South Africa new particle formation has been studied by Laakso et al (2008) and Vakkari et al (2011). These studies revealed new particle formation taking place every sunny day throughout the year. As new particle formation was found to be a regional phenomenon (Laakso et al, 2008; Vakkari et al, 2011), it is expected that new particle formation will occur in polluted areas

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