Multiphase Atmospheric Chemistry of Selected Secondary Organic Aerosols
Abstract
Secondary organic aerosols (SOA) play an important role in the Earth’s radiative budget due to their potential to either warm or cool the atmosphere through light absorption or light scattering, respectively, and to cool or warm the lower atmosphere by acting as cloud condensation nuclei. SOA are air-suspended liquid and semi-solid droplets that form through multiphase chemical processes. Atmospheric photochemical oxidation of volatile organic compounds (VOCs) in the presence of air pollutants, such as NOx (NO + NO2) and the OH radical, promote formation of low volatility organic products that eventually condense to form SOA. To better understand the sources and sinks, formation, and fate of SOA, laboratory studies investigating oxidation of a biogenic VOC as well as anthropogenic emissions of SOA precursors were conducted. The first study (Chapter 3) investigated the OH-initiated oxidation of β-ocimene, a biogenic volatile organic compound (BVOC) released from vegetation, including forests, agricultural landscapes, and grasslands emitted during the daytime. The oxidation of BVOCs in the presence of NOx leads to the formation of functionalized organic nitrate (RONO2) compounds and isomers that easily condense to form SOA. To understand their atmospheric fate, the RONO2 hydrolysis rate constants were quantified and found to be highly pH dependent. The findings of this study provide key insights into the formation and fate of organic nitrates and NOxcycling in forested environments from daytime monoterpenes that were not previously included in atmospheric models. The second study (Chapters 4 and 5) investigated condensed waste emissions generated during Cured-In-Place-Pipe (CIPP) installations. Thisinstallation process is the most popular, least expensive, and most frequently used technology that cures leaking sanitary and stormwater sewers. Waste plumes discharged during pipe manufacture are complex multi-phase mixtures of volatile and semi-volatile organic compounds (VOC and SVOC, respectively), primary organic aerosols and SOA, fine debris of partially cured resin, and direct emission of nanoplastic particles that are all blown into the atmospheric environment at significant concentrations at worksites. This work unveiled a direct emission source of airborne nanoplastic particles as well as substantial concentrations of hazardous compounds and SOA precursors that were previously unrecognized.
Degree
Ph.D.
Advisors
Shepson, Purdue University.
Subject Area
Atmospheric Chemistry|Energy|Atmospheric sciences|Chemistry|Hydrologic sciences
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