Ionic strength effects on the photochemical degradation of acetosyringone in atmospheric deliquescent aerosol particles

Ionic strength effects on the photochemical degradation of acetosyringone in atmospheric deliquescent aerosol particles

A number of laboratory experimental investigations, field campaigns, and modeling results have emphasized the role of aqueous-phase photochemical reactions in the formation of secondary organic aerosols (SOA). However, investigations focused on aqueous-phase reactions under high ionic-strength condi...

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Bibliographic Details
Published in:Atmospheric environment (1994) Vol. 198; pp. 83 - 88
Main Authors: Zhou, Wentao, Mekic, Majda, Liu, Jiangping, Loisel, Gwendal, Jin, Biao, Vione, Davide, Gligorovski, Sasho
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-02-2019
Subjects:
Aerosol
Biomass burning
Ionic strength
Photochemistry
UV-VIS spectroscopy
Ionic strength
UV-VIS spectroscopy
Aerosol
Biomass burning
Photochemistry
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Summary:A number of laboratory experimental investigations, field campaigns, and modeling results have emphasized the role of aqueous-phase photochemical reactions in the formation of secondary organic aerosols (SOA). However, investigations focused on aqueous-phase reactions under high ionic-strength conditions are scarce. Here we study the photochemical behavior of a lignin-derived compound, acetosyringone (AcS), upon addition of an inert salt (NaClO4). The increase in the ionic strength modifies the acidic constant of AcS, enhancing its deprotonation. As a consequence, the UV-VIS absorption spectra of AcS undergo modifications due to red shifts at high ionic strength of the electronic transitions n → π* (from λmax = 297 nm to λmax = 354 nm) and π → π* (from λmax = 214 nm to λmax = 247 nm). At fixed pH = 4, representative of moderately acidic atmospheric aerosol deliquescent particles, the pseudo-first-order rate constants (k1st) of AcS increased by ∼6 times from a dilute aqueous phase to a solution with an effective ionic strength Ieff. = 0.46 M. The rate constant then followed a saturation trend at elevated ionic strength up to Ieff. = 3.1 M. A similar saturation effect of the observed rate constants with ionic strength was observed in presence of NaCl and Na2SO4. Differential absorption spectroscopy (DAS) methodology was applied to examine the changes in absorption spectra of AcS upon prolonged light irradiation. The very subtle pH-induced changes of the absorption spectra of irradiated AcS are due to the formation of acidic compounds emerged upon photochemical transformation of AcS. •The increase of ionic strength leads to a red shift of n→π* absorption band of AcS.•The pKa of AcS, hence acidity is affected with increasing ionic strength.•The decay rate of AcS increases by 6 times from I = 0 M to I = 0.5 M.•Photochemical evolution of AcS leads to acidification of the aerosol particles.
ISSN:1352-2310
1873-2844
DOI:10.1016/j.atmosenv.2018.10.047