Abstract
Abstract. The Norwegian Arctic possesses a unique environment for the detection of new potential chemicals of emerging Arctic concern (CEACs) due to remoteness, sparse population and the low number of local contamination sources. Hence, a contaminant present in Arctic air is still considered a priority indication for its environmental stability and environmental mobility. Today, legacy persistent organic pollutants (POPs) and related conventional environmental pollutants are already well-studied because of their identification as Arctic pollutants in the 1980s. Many of them are implemented and reported in various national and international monitoring activities including the Arctic Monitoring and Assessment Programme (AMAP). These standard monitoring schemes, however, are based on compound-specific quantitative analytical methods. Under such conditions, the possibility for the identification of hitherto unidentified contaminants is limited and random at best. Today, new and advanced technological developments allow a broader, unspecific analytical approach as either targeted multicomponent analysis or suspect and non-target screening strategies. In order to facilitate such a wide range of compounds, a wide-scope sample clean-up method for high-volume air samples based on a combination of adsorbents was applied, followed by comprehensive two-dimensional gas chromatography separation and low-resolution time-of-flight mass spectrometric detection (GC × GC-LRMS). During the study reported here, simultaneous non-target and suspect screening were applied. The detection of over 700 compounds of interest in the particle phase and over 1200 compounds in the gaseous phase is reported. Of those, 62 compounds were confirmed with reference standards and 90 compounds with a probable structure (based upon mass spectrometric interpretation and library spectrum comparison). These included compounds already detected in Arctic matrices and compounds not detected previously (see also Fig. 1). In addition, 241 compounds were assigned a tentative structure or compound class. Hitherto unknown halogenated compounds, which are not listed in the mass spectral libraries used, were also detected and partly identified.
Highlights
A high number of organic chemicals is used today in large quantities
By applying the wide-scope clean-up based on C18 silica and Z-Sep+ combined with Florisil to the air sample extracts from polyurethane foam (PUF) and glass-fibre filters (GFFs), we were able to expand the chemical domain covered compared to established target persistent organic pollutants (POPs) analysis methods, which generally are using concentrated sulfuric acid
Our method covers a broad spectrum of polarity, has sufficient matrix removal, and is for the first time applied to Arctic air samples for the detection and identification of known and new potential CEACs
Summary
A high number of organic chemicals is used today in large quantities. By 2019, the Chemical Abstracts Service (CAS) registrySM contained more than 156 million unique inorganic and organic chemicals. A new non-destructive, wide-scope sample clean-up procedure and a powerful instrumental analysis method were applied to high-volume air samples from an Arctic background monitoring station, aiming at identifying regulated POPs, known CEACs, and emerging or new CEACs. The final separation and detection method was comprehensive two-dimensional gas chromatography (GC × GC), which offers enhanced peak capacity compared to conventional GC and a better separation of matrix residues from analytes, and low-resolution time-of-flight mass spectrometry (LRMS) (Röhler et al, 2020). New potential CEACs were evaluated by comparing them to the PBT classification of the Stockholm Convention (UNEP, 2009b) with a focus on long-range atmospheric transport potential (LRATP)
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