Distinguishing Surface and Bulk Reactivity: Concentration Dependent Kinetics of Iodide Oxidation by Ozone in Microdroplets

19 August 2024, Version 1
This content is a preprint and has not undergone peer review at the time of posting.

Abstract

Iodine oxidation reactions play an important role in environmental, biological, and industrial contexts. The multiphase reaction between aqueous iodide and ozone is of particular interest due to its prevalence in the marine atmosphere and unique reactivity at the air-water interface. Here, we explore the concentration dependence of the I- + O3 reaction in levitated microdroplets under both acidic and basic conditions. To interpret the experimental kinetics, molecular simulations are used to benchmark a kinetic model, which enables insight into the reactivity of the interface, the nanometer-scale sub-surface region, and the bulk interior of the droplet. For all experiments, a kinetic description of gas- and liquid-phase diffusion is critical to interpreting the results. We find that the surface dominates the iodide oxidation kinetics under concentrated and acidic conditions, with the reactive uptake coefficient approaching an upper limit of 10-2 at pH 3. In contrast, reactions in the sub-surface dominate under more dilute and alkaline conditions, with inhibition of the surface reaction at pH 12 and an uptake coefficient that is 10x smaller. The origin of a changing surface mechanism with pH is explored and compared to previous ozone-dependent measurements.

Keywords

microdroplets
mass spectrometry
multiphase kinetics
Molecular Dynamics
Liquids
surface chemistry
Heterogeneous Chemistry

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