Electronic (e-) cigarette aerosol (particle and gas) is a complex mixture of chemicals, of which the profile is highly dependent on device operating parameters and e-liquid flavor formulation. The thermal degradation of the e-liquid solvents propylene glycol and glycerol often generates multifunctional carbonyls that are challenging to quantify because of unavailability of standards. We developed a theoretical method to calculate the relative electrospray ionization sensitivities of hydrazones of organic acids and carbonyls with 2,4-dinitrophenylhydrazine based on their gas-phase basicities (ΔG deprotonation). This method enabled quantification by high-performance liquid chromatography−highresolution mass spectrometry HPLC-HRMS in the absence of chemical standards. Accurate mass and tandem multistage MS (MS n) were used for structure identification of vaping products. We quantified five simple carbonyls, six hydroxycarbonyls, four dicarbonyls, three acids, and one phenolic carbonyl in the e-cigarette aerosol with Classic Tobacco flavor. Our results suggest that hydroxycarbonyls, such as hydroxyacetone, lactaldehyde, and dihydroxyacetone can be significant components in e-cigarette aerosols but have received less attention in the literature and have poorly understood health effects. The data support the radical-mediated e-liquid thermal degradation scheme that has been previously proposed and emphasize the need for more research on the chemistry and toxicology of the complex product formation in e-cigarette aerosols.
Abstract. The reaction of α-pinene with NO3 is an important
sink of both α-pinene and NO3 at night in regions with mixed
biogenic and anthropogenic emissions; however, there is debate on its
importance for secondary organic aerosol (SOA) and reactive nitrogen budgets
in the atmosphere. Previous experimental studies have generally observed low
or zero SOA formation, often due to excessive [NO3] conditions. Here,
we characterize the SOA and organic nitrogen formation from α-pinene + NO3 as a function of nitrooxy peroxy (nRO2) radical fates with
HO2, NO, NO3, and RO2 in an atmospheric chamber. We show that
SOA yields are not small when the nRO2 fate distribution in the chamber
mimics that in the atmosphere, and the formation of pinene nitrooxy
hydroperoxide (PNP) and related organonitrates in the ambient atmosphere can be
reproduced. Nearly all SOA from α-pinene + NO3 chemistry
derives from the nRO2+ RO2 pathway, which alone has an SOA mass
yield of 56 (±7) %. Molecular composition analysis shows that
particulate nitrates are a large (60 %–70 %) portion of the SOA and that
dimer formation is the primary mechanism of SOA production from α-pinene + NO3 under simulated nighttime conditions. Synergistic
dimerization between nRO2 and RO2 derived from ozonolysis and OH
oxidation also contribute to SOA formation and should be considered in
models. We report a 58 (±20) % molar yield of PNP from the
nRO2+ HO2 pathway. Applying these laboratory constraints to
model simulations of summertime conditions observed in the southeast United
States (where 80 % of α-pinene is lost via NO3 oxidation,
leading to 20 % nRO2+ RO2 and 45 % nRO2+ HO2), we estimate yields of 11 % SOA and 7 % particulate nitrate by mass
and 26 % PNP by mole from α-pinene + NO3 in the ambient atmosphere.
These results suggest that α-pinene + NO3 significantly
contributes to the SOA budget and likely constitutes a major removal
pathway of reactive nitrogen from the nighttime boundary layer in mixed
biogenic–anthropogenic areas.
Abstract. The reaction of α-pinene with NO3 is an important sink of both α-pinene and NO3 at night in regions with mixed biogenic and anthropogenic emissions; however, there is debate on its importance for secondary organic aerosol (SOA) and reactive nitrogen budgets in the atmosphere. Previous experimental studies have generally observed low or zero SOA formation, often due to excessive [NO3] conditions. Here, we characterize the SOA and organic nitrogen formation from α-pinene + NO3 as a function of nitrooxy peroxy (nRO2) radical fates with HO2, NO, NO3, and RO2 in an atmospheric chamber. We show that SOA yields are not small when the nRO2 fate distribution in the chamber mimics that in the atmosphere, and the formation of pinene nitrooxy hydroperoxide (PNP) and related organonitrates in the ambient can be reproduced. Nearly all SOA from α-pinene + NO3 chemistry derives from the nRO2 + nRO2 pathway, which alone has an SOA mass yield of 65 (±9) %. Molecular composition analysis shows that particulate nitrates are a large (60–70 %) portion of the SOA, and that dimer formation is the primary mechanism of SOA production from α-pinene + NO3 under simulated nighttime conditions. We estimate an average nRO2 + nRO2 → ROOR branching ratio of ~18 %. Synergistic dimerization between nRO2 and RO2 derived from ozonolysis and OH oxidation also contribute to SOA formation, and should be considered in models. We report a 58 (±20) % molar yield of PNP from the nRO2 + HO2 pathway. Applying these laboratory constraints to model simulations of summertime conditions observed in the Southeast United States (where 80 % of α-pinene is lost via NO3 oxidation, leading to 20 % nRO2 + nRO2 and 45 % nRO2 + HO2) , we estimate yields of 13% SOA and 9% particulate nitrate by mass, and 26 % PNP by mole, from α-pinene + NO3 in the ambient. These results suggest that α-pinene + NO3 significantly contributes to the SOA budget, and likely constitutes a major removal pathway of reactive nitrogen from the nighttime boundary layer in mixed biogenic/anthropogenic areas.
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