Abstract

Abstract. The interactions between organic and inorganic aerosol chemical components are integral to understanding and modelling climate and health-relevant aerosol physicochemical properties, such as volatility, hygroscopicity, light scattering and toxicity. This study presents a synthesis analysis for eight data sets, of non-refractory aerosol composition, measured at a boreal forest site. The measurements, performed with an aerosol mass spectrometer, cover in total around 9 months over the course of 3 years. In our statistical analysis, we use the complete organic and inorganic unit-resolution mass spectra, as opposed to the more common approach of only including the organic fraction. The analysis is based on iterative, combined use of (1) data reduction, (2) classification and (3) scaling tools, producing a data-driven chemical mass balance type of model capable of describing site-specific aerosol composition. The receptor model we constructed was able to explain 83±8 % of variation in data, which increased to 96±3 % when signals from low signal-to-noise variables were not considered. The resulting interpretation of an extensive set of aerosol mass spectrometric data infers seven distinct aerosol chemical components for a rural boreal forest site: ammonium sulfate (35±7 % of mass), low and semi-volatile oxidised organic aerosols (27±8 % and 12±7 %), biomass burning organic aerosol (11±7 %), a nitrate-containing organic aerosol type (7±2 %), ammonium nitrate (5±2 %), and hydrocarbon-like organic aerosol (3±1 %). Some of the additionally observed, rare outlier aerosol types likely emerge due to surface ionisation effects and likely represent amine compounds from an unknown source and alkaline metals from emissions of a nearby district heating plant. Compared to traditional, ion-balance-based inorganics apportionment schemes for aerosol mass spectrometer data, our statistics-based method provides an improved, more robust approach, yielding readily useful information for the modelling of submicron atmospheric aerosols physical and chemical properties. The results also shed light on the division between organic and inorganic aerosol types and dynamics of salt formation in aerosol. Equally importantly, the combined methodology exemplifies an iterative analysis, using consequent analysis steps by a combination of statistical methods. Such an approach offers new ways to home in on physicochemically sensible solutions with minimal need for a priori information or analyst interference. We therefore suggest that similar statistics-based approaches offer significant potential for un- or semi-supervised machine-learning applications in future analyses of aerosol mass spectrometric data.

Highlights

  • Along with particle size, aerosol chemical composition is fundamental in understanding aerosol physicochemical properties such as hygroscopicity, volatility, optics and toxicity (Bilde et al, 2015; Swietlicki et al, 2008; Zimmermann, 2015)

  • All ratios and fractions of signals presented are calculated from the corresponding final spectra (P-III)

  • Organic nitrogen seems to be a larger component than ammonium nitrate for the site

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Summary

Introduction

Aerosol chemical composition is fundamental in understanding aerosol physicochemical properties such as hygroscopicity, volatility, optics and toxicity (Bilde et al, 2015; Swietlicki et al, 2008; Zimmermann, 2015). Äijälä et al.: Constructing a data-driven receptor model for organic and inorganic aerosol position of aerosol in near real time This enables basic chemical speciation into organic and common inorganic ion species, and produces a wealth of complex mass spectrometric data. It has since become clear that these data sets, superficially hard to interpret, are rich in chemical information and their statistical analysis yields considerable new knowledge Tapping into this information source requires use of advanced analysis tools and chemometric methods The positive matrix factorisation algorithm (PMF; Paatero and Tapper, 1994) has achieved a predominant status as the state-of-the-art analysis tool for deconvolving aerosol mass spectrometric data Factorisation methods such as PMF notably allow for the condensation of information found in high-dimension data matrices into a manageable number of factors, corresponding to aerosol chemical species, sources or processes, for example. Data reduction often allows for improved visualisation, aiding in interpretation of the underlying aerosol chemical phenomena

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