Coupled Interfacial and Bulk Kinetics Govern the Timescales of Multiphase Ozonolysis Reactions.

Chemical transformations in aerosols impact the lifetime of particle phase species, the fate of atmospheric pollutants, and both climate- and health-relevant aerosol properties. Timescales for multiphase reactions of ozone in atmospheric aqueous phases are governed by coupled kinetic processes between the gas phase, the particle interface, and its bulk, which respond dynamically to reactive consumption of O. However, models of atmospheric aerosol reactivity often do not account for the coupled nature of multiphase processes. To examine these dynamics, we use new and prior experimental observations of aqueous droplet reaction kinetics, including three systems with a range of surface affinities and ozonolysis rate coefficients (-aconitic acid (CHO), maleic acid (CHO), and sodium nitrite (NaNO)). Using literature rate coefficients and thermodynamic properties, we constrain a simple two-compartment stochastic kinetic model which resolves the interface from the particle bulk and represents O partitioning, diffusion, and reaction as a coupled kinetic system. Our kinetic model accurately predicts decay kinetics across all three systems, demonstrating that both the thermodynamic properties of O and the coupled kinetic and diffusion processes are key to making accurate predictions. An enhanced concentration of adsorbed O, compared to gas and bulk phases is rapidly maintained and remains constant even as O is consumed by reaction. Multiphase systems dynamically seek to achieve equilibrium in response to reactive O loss, but this is hampered at solute concentrations relevant to aqueous aerosol by the rate of O arrival in the bulk by diffusion. As a result, bulk-phase O becomes depleted from its Henry's law solubility. This bulk-phase O depletion limits reaction timescales for relatively slow-reacting organic solutes with low interfacial affinity (i.e., -aconitic and maleic acids, with ≈ 10-10 M s), which is in contrast to fast-reacting solutes with higher surface affinity (i.e., nitrite, with ≈ 10 M s) where surface reactions strongly impact the observed decay kinetics.