Single-particle experiments measuring humidity and inorganic salt effects on gas-particle partitioning of butenedial

• Published in: Atmospheric chemistry and physics Vol. 19; no. 22; pp. 14195 - 14209
• Main Authors: Birdsall, Adam W, Hensley, Jack C, Kotowitz, Paige S, Huisman, Andrew J, Keutsch, Frank N
• Format: Journal Article
• Language: English
• Published: Katlenburg-Lindau Copernicus GmbH 26.11.2019; Copernicus Publications
• Subjects: Aerosol particles; Aerosols; Analysis; Aromatic compounds; Atmospheric aerosols; Atmospheric physics; Balancing; Chemical partition; Chlorides; Evaporation; Evaporation rate; Experiments; Fate; Glyoxal; Humidity; Humidity measurement; Hydrates; Inorganic salts; Laboratories; Laboratory experiments; Levitation; Mass spectrometry; Mass spectroscopy; Measurement; Moisture content; Oxidation; Oxidation-reduction reactions; Particle composition; Partitioning; Relative humidity; Salt effect; Salting; Salts; Sodium; Sodium chloride; Sodium sulfate; Spectroscopy; Sulfates; Vapor pressure; Vapour pressure; Volatility; Water; Water content
• ISSN: 1680-7324; 1680-7316; 1680-7324
• DOI: 10.5194/acp-19-14195-2019

An improved understanding of the fate and properties of atmospheric aerosol particles requires a detailed process-level understanding of fundamental factors influencing the aerosol, including partitioning of aerosol components between the gas and particle phases. Laboratory experiments with levitated particles provide a way to study fundamental aerosol processes over timescales relevant to the multiday lifetime of atmospheric aerosol particles, in a controlled environment in which various characteristics relevant to atmospheric aerosol can be prepared (e.g., high surface-to-volume ratio, highly concentrated or supersaturated solutions, changes to relative humidity). In this study, the four-carbon unsaturated compound butenedial, a dialdehyde produced by oxidation of aromatic compounds that undergoes hydration in the presence of water, was used as a model organic aerosol component to investigate different factors affecting gas–particle partitioning, including the role of lower-volatility “reservoir” species such as hydrates, timescales involved in equilibration between higher- and lower-volatility forms, and the effect of inorganic salts. The experimental approach was to use a laboratory system coupling particle levitation in an electrodynamic balance (EDB) with particle composition measurement via mass spectrometry (MS). In particular, by fitting measured evaporation rates to a kinetic model, the effective vapor pressure was determined for butenedial and compared under different experimental conditions, including as a function of ambient relative humidity and the presence of high concentrations of inorganic salts. Even under dry (RH<5 %) conditions, the evaporation rate of butenedial is orders of magnitude lower than what would be expected if butenedial existed purely as a dialdehyde in the particle, implying an equilibrium strongly favoring hydrated forms and the strong preference of certain dialdehyde compounds to remain in a hydrated form even under lower water content conditions. Butenedial exhibits a salting-out effect in the presence of sodium chloride and sodium sulfate, in contrast to glyoxal. The outcomes of these experiments are also helpful in guiding the design of future EDB-MS experiments.