Your search keyword '"Campos TL"' showing total 2 results

1. Volatile chemical product emissions enhance ozone and modulate urban chemistry.

Author

Coggon MM, Gkatzelis GI, McDonald BC, Gilman JB, Schwantes RH, Abuhassan N, Aikin KC, Arend MF, Berkoff TA, Brown SS, Campos TL, Dickerson RR, Gronoff G, Hurley JF, Isaacman-VanWertz G, Koss AR, Li M, McKeen SA, Moshary F, Peischl J, Pospisilova V, Ren X, Wilson A, Wu Y, Trainer M, and Warneke C

Subjects

Air Pollutants chemistry, Air Pollution, Cities, Environmental Monitoring methods, Europe, Humans, Models, Theoretical, Monoterpenes analysis, New York City, Nitrogen Oxides analysis, Nitrogen Oxides chemistry, Odorants analysis, Population Density, Vehicle Emissions analysis, Volatile Organic Compounds chemistry, Air Pollutants analysis, Ozone, Volatile Organic Compounds analysis

Abstract

Decades of air quality improvements have substantially reduced the motor vehicle emissions of volatile organic compounds (VOCs). Today, volatile chemical products (VCPs) are responsible for half of the petrochemical VOCs emitted in major urban areas. We show that VCP emissions are ubiquitous in US and European cities and scale with population density. We report significant VCP emissions for New York City (NYC), including a monoterpene flux of 14.7 to 24.4 kg ⋅ d -1 ⋅ km -2 from fragranced VCPs and other anthropogenic sources, which is comparable to that of a summertime forest. Photochemical modeling of an extreme heat event, with ozone well in excess of US standards, illustrates the significant impact of VCPs on air quality. In the most populated regions of NYC, ozone was sensitive to anthropogenic VOCs (AVOCs), even in the presence of biogenic sources. Within this VOC-sensitive regime, AVOCs contributed upwards of ∼20 ppb to maximum 8-h average ozone. VCPs accounted for more than 50% of this total AVOC contribution. Emissions from fragranced VCPs, including personal care and cleaning products, account for at least 50% of the ozone attributed to VCPs. We show that model simulations of ozone depend foremost on the magnitude of VCP emissions and that the addition of oxygenated VCP chemistry impacts simulations of key atmospheric oxidation products. NYC is a case study for developed megacities, and the impacts of VCPs on local ozone are likely similar for other major urban regions across North America or Europe., Competing Interests: The authors declare no competing interest.

Published

2021

2. Quantification of organic aerosol and brown carbon evolution in fresh wildfire plumes.

Author

Palm BB, Peng Q, Fredrickson CD, Lee BH, Garofalo LA, Pothier MA, Kreidenweis SM, Farmer DK, Pokhrel RP, Shen Y, Murphy SM, Permar W, Hu L, Campos TL, Hall SR, Ullmann K, Zhang X, Flocke F, Fischer EV, and Thornton JA

Subjects

Aerosols, Environmental Monitoring, Particulate Matter, United States, Air Pollutants chemistry, Carbon analysis, Smoke, Wildfires

Abstract

The evolution of organic aerosol (OA) and brown carbon (BrC) in wildfire plumes, including the relative contributions of primary versus secondary sources, has been uncertain in part because of limited knowledge of the precursor emissions and the chemical environment of smoke plumes. We made airborne measurements of a suite of reactive trace gases, particle composition, and optical properties in fresh western US wildfire smoke in July through August 2018. We use these observations to quantify primary versus secondary sources of biomass-burning OA (BBPOA versus BBSOA) and BrC in wildfire plumes. When a daytime wildfire plume dilutes by a factor of 5 to 10, we estimate that up to one-third of the primary OA has evaporated and subsequently reacted to form BBSOA with near unit yield. The reactions of measured BBSOA precursors contribute only 13 ± 3% of the total BBSOA source, with evaporated BBPOA comprising the rest. We find that oxidation of phenolic compounds contributes the majority of BBSOA from emitted vapors. The corresponding particulate nitrophenolic compounds are estimated to explain 29 ± 15% of average BrC light absorption at 405 nm (BrC Abs 405 ) measured in the first few hours of plume evolution, despite accounting for just 4 ± 2% of average OA mass. These measurements provide quantitative constraints on the role of dilution-driven evaporation of OA and subsequent radical-driven oxidation on the fate of biomass-burning OA and BrC in daytime wildfire plumes and point to the need to understand how processing of nighttime emissions differs., Competing Interests: The authors declare no competing interest.

Published

2020