Litcius/Paper detail

Determining Activity Coefficients of SOA from Isothermal Evaporation in a Laboratory Chamber

Xiaoxi Liu, Douglas A. Day, Jordan Krechmer, Paul J. Ziemann, J. L. Jiménez

2020Environmental Science & Technology Letters28 citationsDOIOpen Access PDF

Abstract

Nonideal molecular interactions in aerosol particles influence the partitioning of semivolatile organic compounds (SVOCs). However, few direct measurements exist that determine activity coefficients (γ), which quantify nonideality, for individual organic compounds in different atmospheric mixtures. By measuring the isothermal evaporation of SOA formed from multifunctional SVOCs in an environmental chamber, this study determines the mole-fraction-based γ of the bulk SOA in a variety of pre-existing chemically complex particles, approximated as if the bulk SOA behaved like a single SVOC. These multicomponent mixtures contain molecular structures commonly found in the atmosphere. When treated as a single liquid phase, γ of the bulk SOA tends to increase from ∼1 to ∼5 as the organic seeds and the SOA have more differing polarities. A high computed γ value of 74 for a wet ammonium sulfate-SOA system indicates phase separation. The γ for some individual species was also quantified based on gas-phase measurements and AIOMFAC model predictions. However, the bulk SOA γ cannot be explained by the simplified speciated SVOC–seed interactions, suggesting incomplete compositional understanding of the bulk SOA. These results demonstrate a method to quantify nonideal behavior and show that it can occur in multicomponent mixtures and therefore influence OA formation, evolution, and lifetimes.

Topics & Concepts

EvaporationIsothermal processAerosolPhase (matter)ChemistryAmmonium sulfateAtmosphere (unit)Fraction (chemistry)AmmoniumAnalytical Chemistry (journal)Chemical physicsThermodynamicsMaterials scienceChemical engineeringEnvironmental chemistryChromatographyOrganic chemistryPhysicsEngineeringAtmospheric chemistry and aerosolsAir Quality and Health ImpactsAtmospheric Ozone and Climate