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Your search keyword '"Lauren A. Garofalo"' showing total 7 results
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7 results on '"Lauren A. Garofalo"'

2. Formation and Evolution of Catechol-Derived SOA Mass, Composition, Volatility, and Light Absorption

Author

Carley D. Fredrickson, Brett B. Palm, Ben H. Lee, Xuan Zhang, John J. Orlando, Geoffrey S. Tyndall, Lauren A. Garofalo, Matson A. Pothier, Delphine K. Farmer, Zachary C. J. Decker, Michael A. Robinson, Steven S. Brown, Shane M. Murphy, Yingjie Shen, Amy P. Sullivan, Siegfried Schobesberger, and Joel A. Thornton

Subjects
Atmospheric Science, Space and Planetary Science, Geochemistry and Petrology
Published
2022
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3. Dilution and photooxidation driven processes explain the evolution of organic aerosol in wildfire plumes

Author

Ali Akherati, Yicong He, Lauren A. Garofalo, Anna L. Hodshire, Delphine K. Farmer, Sonia M. Kreidenweis, Wade Permar, Lu Hu, Emily V. Fischer, Coty N. Jen, Allen H. Goldstein, Ezra J. T. Levin, Paul J. DeMott, Teresa L. Campos, Frank Flocke, John M. Reeves, Darin W. Toohey, Jeffrey R. Pierce, and Shantanu H. Jathar

Subjects
Chemistry (miscellaneous), Environmental Chemistry, Pollution, Analytical Chemistry
Abstract

Wildfires are a source of primary aerosols and precursors for secondary aerosols to the atmosphere. In this work, we discover that the evolution of these aerosols depends strongly on the coupled effects of dilution, photooxidation, and partitioning.

Published
2022
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4. Closing the reactive carbon flux budget: Observations from dual mass spectrometers over a coniferous forest

Author

Michael P Vermeuel, Dylan B. Millet, Delphine Farmer, Matson A. Pothier, Michael F. Link, Mj Riches, Sara Williams, and Lauren A. Garofalo

Abstract

We use observations from dual high-resolution mass spectrometers to characterize ecosystem-atmosphere fluxes of reactive carbon across an extensive range of volatile organic compounds (VOCs) and test how well that exchange is represented in current chemical transport models. Measurements combined proton-transfer reaction mass spectrometry (PTRMS) and iodide chemical ionization mass spectrometry (ICIMS) over a Colorado pine forest; together, these techniques have been shown to capture the majority of ambient VOC abundance and reactivity. Total VOC mass and associated OH reactivity fluxes were dominated by emissions of 2-methyl-3-buten-2-ol, monoterpenes, and small oxygenated VOCs, with a small number of compounds detected by PTRMS driving the majority of both net and upward exchanges. Most of these dominant species are explicitly included in chemical models, and we find here that GEOS-Chem accurately simulates the net and upward VOC mass and OH reactivity fluxes under clear sky conditions. However, large upward terpene fluxes occurred during sustained rainfall, and these are not captured by the model. Far more species contributed to the downward fluxes than are explicitly modeled, leading to a major underestimation of this key sink of atmospheric reactive carbon. This model bias mainly reflects missing and underestimated concentrations of depositing species, though inaccurate deposition velocities also contribute. The deposition underestimate is particularly large for assumed isoprene oxidation products, organic acids, and nitrates—species that are primarily detected by ICIMS. Ecosystem-atmosphere fluxes of ozone reactivity were dominated by sesquiterpenes and monoterpenes, highlighting the importance of these species for predicting near-surface ozone, oxidants, and aerosols.

Published
2023
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6. The Sea Spray Chemistry and Particle Evolution study (SeaSCAPE): Overview and experimental methods

Author

Jon S. Sauer, Kathryn J. Mayer, Christopher Lee, Michael R. Alves, Sarah Amiri, Cristina J. Bahaveolos, Emily B. Franklin, Daniel R. Crocker, Duyen Dang, Julie Dinasquet, Lauren A. Garofalo, Chathuri P. Kaluarachchi, Delaney B. Kilgour, Liora E. Mael, Brock A. Mitts, Daniel R. Moon, Alexia N. Moore, Clare K. Morris, Catherine A. Mullenmeister, Chi-Min Ni, Matthew A. Pendergraft, Daniel Petras, Rebecca M. C. Simpson, Stephanie Smith, Paul R. Tumminello, Joseph L. Walker, Paul J. DeMott, Delphine K. Farmer, Allen H. Goldstein, Vicki H. Grassian, Jules S. Jaffe, Francesca Malfatti, Todd R. Martz, Jonathan H. Slade, Alexei V. Tivanski, Timothy H. Bertram, Christopher D. Cappa, Kimberly A. Prather, Sauer, J. S., Mayer, K. J., Lee, C., Alves, M. R., Amiri, S., Bahaveolos, C. J., Franklin, E. B., Crocker, D. R., Dang, D., Dinasquet, J., Garofalo, L. A., Kaluarachchi, C. P., Kilgour, D. B., Mael, L. E., Mitts, B. A., Moon, D. R., Moore, A. N., Morris, C. K., Mullenmeister, C. A., Ni, C. -M., Pendergraft, M. A., Petras, D., Simpson, R. M. C., Smith, S., Tumminello, P. R., Walker, J. L., Demott, P. J., Farmer, D. K., Goldstein, A. H., Grassian, V. H., Jaffe, J. S., Malfatti, F., Martz, T. R., Slade, J. H., Tivanski, A. V., Bertram, T. H., Cappa, C. D., and Prather, K. A.

Subjects
Aerosols, Atmosphere, Oceans and Seas, Oceans and Sea, Public Health, Environmental and Occupational Health, microbes [Seawater], General Medicine, respiratory system, Management, Monitoring, Policy and Law, Seawater: microbes, complex mixtures, Phytoplankton, Environmental Chemistry, Seawater, Aerosol
Abstract

Marine aerosols strongly influence climate through their interactions with solar radiation and clouds. However, significant questions remain regarding the influences of biological activity and seawater chemistry on the flux, chemical composition, and climate-relevant properties of marine aerosols and gases. Wave channels, a traditional tool of physical oceanography, have been adapted for large-scale ocean-atmosphere mesocosm experiments in the laboratory. These experiments enable the study of aerosols under controlled conditions which isolate the marine system from atmospheric anthropogenic and terrestrial influences. Here, we present an overview of the 2019 Sea Spray Chemistry and Particle Evolution (SeaSCAPE) study, which was conducted in an 11 800 L wave channel which was modified to facilitate atmospheric measurements. The SeaSCAPE campaign sought to determine the influence of biological activity in seawater on the production of primary sea spray aerosols, volatile organic compounds (VOCs), and secondary marine aerosols. Notably, the SeaSCAPE experiment also focused on understanding how photooxidative aging processes transform the composition of marine aerosols. In addition to a broad range of aerosol, gas, and seawater measurements, we present key results which highlight the experimental capabilities during the campaign, including the phytoplankton bloom dynamics, VOC production, and the effects of photochemical aging on aerosol production, morphology, and chemical composition. Additionally, we discuss the modifications made to the wave channel to improve aerosol production and reduce background contamination, as well as subsequent characterization experiments. The SeaSCAPE experiment provides unique insight into the connections between marine biology, atmospheric chemistry, and climate-relevant aerosol properties, and demonstrates how an ocean-atmosphere-interaction facility can be used to isolate and study reactions in the marine atmosphere in the laboratory under more controlled conditions. This journal is

Published
2022

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