Login / Signup

Isomer-Resolved Mobility-Mass Analysis of α-Pinene Ozonolysis Products.

Aurora SkyttäJian GaoRunlong CaiMikael EhnLauri R AhonenTheo KurténZhibin WangMatti P RissanenJuha Kangasluoma
Published in: The journal of physical chemistry. A (2022)
Highly oxygenated organic molecules (HOMs) are important sources of atmospheric aerosols. Resolving the molecular-level formation mechanisms of these HOMs from freshly emitted hydrocarbons improves the understanding of aerosol properties and their influence on the climate. In this study, we measure the electrical mobility and mass-to-charge ratio of α-pinene oxidation products using a secondary electrospray-differential mobility analyzer-mass spectrometer (SESI-DMA-MS). The mass-mobility spectrum of the oxidation products is measured with seven different reagent ions generated by the electrospray. We analyzed the mobility-mass spectra of the oxidation products C 9-10 H 14-18 O 2-6 . Our results show that acetate and chloride yield the highest charging efficiencies. Analysis of the mobility spectra suggests that the clusters have 1-5 isomeric structures (i.e., ion-molecule cluster structures with distinct mobilities), and the number is affected by the reagent ion. Most of the isomers are likely cluster isomers originating from binding of the reagent ion to different sites of the molecule. By comparing the number of observed isomers and measured mobilities and collision cross sections between standard pinanediol and pinonic acid to the values observed for C 10 H 18 O 2 and C 10 H 16 O 3 produced from oxidation of α-pinene, we confirm that pinanediol and pinonic acid are the only isomers for these elemental compositions in our experimental conditions. Our study shows that the SESI-DMA-MS produces new information from the first steps of oxidation of α-pinene.
Keyphrases
  • mass spectrometry
  • hydrogen peroxide
  • high resolution
  • multiple sclerosis
  • water soluble
  • ms ms
  • liquid chromatography
  • climate change
  • electron transfer
  • nitric oxide
  • healthcare
  • density functional theory
  • quantum dots