Abstract
Reaction products from the ozonolysis of unsaturated lipids at gas–liquid interfaces have the potential to significantly influence the chemical and physical properties of organic aerosols in the atmosphere. In this study, the gas-phase dissociation behavior of lipid secondary ozonides is investigated using ion-trap mass spectrometry. Secondary ozonides were formed by reaction between a thin film of unsaturated lipids (fatty acid methyl esters or phospholipids) with ozone before being transferred to the gas phase as [M + Na]+ ions by electrospray ionization. Activation of the ionized ozonides was performed by either energetic collisions with helium buffer-gas or laser photolysis, with both processes yielding similar product distributions. Products arising from the decomposition of the ozonides were characterized by their mass-to-charge ratio and subsequent ion-molecule reactions. Product assignments were rationalized as arising from initial homolysis of the ozonide oxygen–oxygen bond with subsequent decomposition of the nascent biradical intermediate. In addition to classic aldehyde and carbonyl oxide-type fragments, carbon-centered radicals were identified with a number of decomposition pathways that indicated facile unimolecular radical migration. These findings reveal that photoactivation of secondary ozonides formed by the reaction of aerosol-bound lipids with tropospheric ozone may initiate radical-mediated chemistry within the particle resulting in surface modification.Graphical ᅟ
Highlights
The ions at m/z 209 and 225 observed in the full MS spectrum (Figure 1a) are assigned as an aldehyde (9oxononanoic acid methyl ester) and carboxylic acid (9methoxy-9-oxononanoic acid), both of which are well known products of lipid ozonolysis (cf Scheme 1)
Large amounts (Tg year–1) of short-chain alkenes, in the form of volatile organic compounds, are emitted into the Electronic supplementary material The online version of this article contains supplementary material, which is available to authorized users.S
Ozonolysis of a thin film of methyl oleate (FAME 9Z-18:1) over several min resulted in complete oxidation and formation of several oxidation products, including secondary ozonides
Summary
The ions at m/z 209 and 225 observed in the full MS spectrum (Figure 1a) are assigned as an aldehyde (9oxononanoic acid methyl ester) and carboxylic acid (9methoxy-9-oxononanoic acid), both of which are well known products of lipid ozonolysis (cf Scheme 1). The CID spectrum acquired from the [M + O3 + Na]+ ion of FAME 9Z-18:1 observed at m/z 367 is shown, while Scheme 2 outlines the possible products that can be formed following activation of the secondary ozonide.
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