Formation
and Evolution of aqSOA from Aqueous-Phase
Reactions of Phenolic Carbonyls: Comparison between Ammonium Sulfate
and Ammonium Nitrate Solutions
posted on 2018-07-09, 00:00authored byDan Dan Huang, Qi Zhang, Heidi H. Y. Cheung, Lu Yu, Shan Zhou, Cort Anastasio, Jeremy D. Smith, Chak K. Chan
We investigate the effects of sulfate
and nitrate on the formation
and evolution of secondary organic aerosol formed in the aqueous phase
(aqSOA) from photooxidation of two phenolic carbonyls emitted from
wood burning. AqSOA was formed efficiently from the photooxidation
of both syringaldehyde (C9H10O4)
and acetosyringone (C10H12O4) in
ammonium sulfate and ammonium nitrate solutions, with mass yields
ranging from 30% to 120%. Positive matrix factorization on the organic
mass spectra acquired by an Aerosol Mass Spectrometer revealed a combination
of functionalization, oligomerization, and fragmentation processes
in the chemical evolution of aqSOA. Functionalization and oligomerization
dominated in the first 4 h of reaction, with phenolic oligomers and
their derivatives significantly contributing to aqSOA formation; and oxidation
of the first-generation products led to an abundance of oxygenated
ring-opening products. Degradation rates of syringaldehyde and acetosyringone
in nitrate solutions were 1.5 and 3.5 times faster than rates in sulfate
solutions, and aqSOA yields in nitrate experiments are twice as high
as in sulfate experiments. Nitrate likely promoted the reactions because
it is a photolytic source of OH radicals, while sulfate is not, highlighting
the importance of aerosol-phase nitrate in the formation of aqSOA
by facilitating the photooxidation of organic precursors.