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The persistence of a proxy for cooking emissions in megacities: a kinetic study of the ozonolysis of self-assembled films by simultaneous Small & Wide Angle X-ray Scattering (SAXS/WAXS) and Raman microscopy

DOI: 10.1039/D0FD00088D DOI Help

Authors: Adam Milsom (University of Birmingham) , Adam M. Squires (University of Bath) , Ben Woden (University of Reading) , Nicholas J. Terrill (Diamond Light Source) , Andrew D. Ward (Central Laser Facility, Research Complex at Harwell) , Christian Pfrang (University of Birmingham; University of Reading)
Co-authored by industrial partner: No

Type: Journal Paper
Journal: Faraday Discussions

State: Published (Approved)
Published: September 2020
Diamond Proposal Number(s): 21663 , 23096

Open Access Open Access

Abstract: Cooking emissions account for a significant proportion of the organic aerosol emitted into the urban environment and high pollution events have been linked to an increased organic content on urban particulate matter surfaces. We present a kinetic study on surface coatings of self-assembled (semi-solid) oleic acid-sodium oleate cooking aerosol proxies undergoing ozonolysis. We found a clear film thickness-dependent kinetic behaviour and measured the effect of the organic phase on the kinetics for this system. In addition to the thickness-dependent kinetics, we show that significant fractions of unreacted proxy remain at the end of extensive ozone exposure and that this effect scales approximately linearly with film thickness, suggesting that a late-stage inert reaction product may form to inhibit reaction progress – effectively building up an inert crust. We determine this by using a range of simultaneous analytical techniques; most notably Small-Angle X-ray Scattering (SAXS) has been used for the first time to measure reaction kinetics of films of a wide range of thicknesses from ca. 0.59 to 73 µm with films < 10 µm thick being of potential atmospheric relevance. These observations have implications for the evolution of particulate matter in the urban environment, potentially extending the atmospheric lifetimes of harmful aerosol components and affecting the local urban air quality and climate.

Journal Keywords: Physical Chemistry; Atmospheric Chemistry; Pollution

Subject Areas: Chemistry, Environment

Instruments: I22-Small angle scattering & Diffraction

Other Facilities: Central Laser Facility (Raman spectroscopy setup)


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