| Literature DB >> 32559089 |
Ali Akherati1, Yicong He1, Matthew M Coggon2,3, Abigail R Koss4, Anna L Hodshire5, Kanako Sekimoto2, Carsten Warneke2,3, Joost de Gouw6, Lindsay Yee7, John H Seinfeld8, Timothy B Onasch9, Scott C Herndon9, Walter B Knighton10, Christopher D Cappa11, Michael J Kleeman11, Christopher Y Lim4, Jesse H Kroll4, Jeffrey R Pierce5, Shantanu H Jathar1.
Abstract
Biomass burning is the largest combustion-related source of volatile organic compounds (VOCs) to the atmosphere. We describe the development of a state-of-the-science model to simulate the photochemical formation of secondary organic aerosol (SOA) from biomass-burning emissions observed in dry (RH <20%) environmental chamber experiments. The modeling is supported by (i) new oxidation chamber measurements, (ii) detailed concurrent measurements of SOA precursors in biomass-burning emissions, and (iii) development of SOA parameters for heterocyclic and oxygenated aromatic compounds based on historical chamber experiments. We find that oxygenated aromatic compounds, including phenols and methoxyphenols, account for slightly less than 60% of the SOA formed and help our model explain the variability in the organic aerosol mass (R2 = 0.68) and O/C (R2 = 0.69) enhancement ratios observed across 11 chamber experiments. Despite abundant emissions, heterocyclic compounds that included furans contribute to ∼20% of the total SOA. The use of pyrolysis-temperature-based or averaged emission profiles to represent SOA precursors, rather than those specific to each fire, provide similar results to within 20%. Our findings demonstrate the necessity of accounting for oxygenated aromatics from biomass-burning emissions and their SOA formation in chemical mechanisms.Entities:
Year: 2020 PMID: 32559089 DOI: 10.1021/acs.est.0c01345
Source DB: PubMed Journal: Environ Sci Technol ISSN: 0013-936X Impact factor: 9.028