Interference of sea salt in capture vaporizer-ToF-ACSM measurements of biomass burning organic aerosols in coastal locations

Authors

Adhitya Sutresna, School of Geography
Melita Keywood, Commonwealth Scientific and Industrial Research Organisation
Clare Paton-Walsh, Faculty of Science, Medicine and Health
Jack Simmons, Faculty of Science, Medicine and Health
Caleb Mynard, Commonwealth Scientific and Industrial Research Organisation
Quang Dang, Faculty of Science, Medicine and Health
Michihiro Mochida, Nagoya University
Sho Ohata, Nagoya University
Sonia Afsana, Nagoya University
Bhagawati Kunwar, Chubu University
Kimitaka Kawamura, Chubu University
Ruhi Humphries, Commonwealth Scientific and Industrial Research Organisation
Erin Dunne, Commonwealth Scientific and Industrial Research Organisation
Jason Ward, Commonwealth Scientific and Industrial Research Organisation
James Harnwell, Commonwealth Scientific and Industrial Research Organisation
Fabienne Reisen, Commonwealth Scientific and Industrial Research Organisation
Kathryn Emmerson, Commonwealth Scientific and Industrial Research Organisation
Alan Griffiths, Australian Nuclear Science and Technology Organisation
Alastair Williams, Australian Nuclear Science and Technology Organisation
Robyn Schofield, School of Geography
Peter Rayner, School of Geography

Publication Name

Environmental Science: Atmospheres

Abstract

The capture vaporizer (CV) was developed to reduce uncertainties in non-refractory aerosol composition measurements made using the aerosol mass spectrometer (AMS) and the aerosol chemical speciation monitor (ACSM). Use of the capture vaporizer has achieved this by improving the instruments' collection efficiency to ∼1, but it has also lengthened the aerosol particles' residence times in the instrument, which has changed AMS and ACSM measurements using the standard vaporizer by altering known fragmentation patterns of organic marker species and increasing the likelihood of detecting refractory particles such as sea salt at typical operating temperatures (∼550 °C). This study reports that the changes affected by the capture vaporizer leads to sea salt particles interfering with measurements of biomass burning organic aerosols (BBOA) in environments where both particle sources are present as the ACSM's unit mass resolution is unable to distinguish between different molecules with the same molecular mass. Demonstration of this interference was performed using CV-Time of Flight-ACSM (CV-ToF-ACSM) measurements at two coastal Australian locations: the Kennaook-Cape Grim Baseline Air Pollution Station, Tasmania; and the site of the COALA-2020 (Characterizing Organics and Aerosol Loading over Australia 2020) campaign in New South Wales. Concentrations of BBOA marker ions m/z 60 and m/z 73 were examined at both locations, which showed two distinct branches of points: one where the two marker ions were positively correlated and one that was uncorrelated. This was due to m/z 60 also being a marker for sea salt. A threshold concentration of m/z 73 was established at each location to recognise periods where m/z 60 originated from BBOA. Lower concentrations of m/z 44 and radon when m/z 73 concentration was below the BBOA threshold indicated that m/z 60 concentration during these periods corresponded to inorganic particles of marine origin. Positive Matrix Factorization has also been shown to separate m/z 60 concentration from the two sources. This study suggests that using CV-ToF-ACSMs in coastal locations that are exposed to biomass burning smoke needs to consider sea salt interference when identifying BBOA.

Open Access Status

This publication may be available as open access

Funding Sponsor

University of Melbourne