Your search keyword '"Coggon, Matthew M."' showing total 273 results

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

Author

Coggon, Matthew M., Gkatzelis, Georgios I., McDonald, Brian C., Gilman, Jessica B., Schwantes, Rebecca H., Abuhassan, Nader, Aikin, Kenneth C., Arend, Mark F., Berkoff, Timothy A., Brown, Steven S., Campos, Teresa L., Dickerson, Russell R., Gronoff, Guillaume, Hurley, James F., Isaacman-VanWertz, Gabriel, Koss, Abigail R., Li, Meng, McKeen, Stuart A., Moshary, Fred, Peischl, Jeff, Pospisilova, Veronika, Ren, Xinrong, Wilson, Anna, Wu, Yonghua, Trainer, Michael, and Warneke, Carsten

Published

2021

2. Urban ozone formation and sensitivities to volatile chemical products, cooking emissions, and NO x upwind of and within two Los Angeles Basin cities.

Author

Stockwell, Chelsea E., Coggon, Matthew M., Schwantes, Rebecca H., Harkins, Colin, Verreyken, Bert, Lyu, Congmeng, Zhu, Qindan, Xu, Lu, Gilman, Jessica B., Lamplugh, Aaron, Peischl, Jeff, Robinson, Michael A., Veres, Patrick R., Li, Meng, Rollins, Andrew W., Zuraski, Kristen, Baidar, Sunil, Liu, Shang, Kuwayama, Toshihiro, and Brown, Steven S.

Subjects

CITIES & towns, VOLATILE organic compounds, EMISSION inventories, OZONE, FOSSIL fuels

Abstract

Volatile chemical products (VCPs) and other non-traditional anthropogenic sources, such as cooking, contribute substantially to the volatile organic compound (VOC) budget in urban areas, but their impact on ozone formation is less certain. This study employs Lagrangian box modeling and sensitivity analyses to evaluate ozone response to sector-specific VOC and nitrogen oxide (NOx) emissions in two Los Angeles (LA) Basin cities during the summer of 2021. The model simulated the photochemical processing and transport of temporally and spatially gridded emissions from the FIVE-VCP-NEI17NRT inventory and accurately simulates the variability and magnitude of O3, NOx, and speciated VOCs in Pasadena, CA. VOC sensitivity analyses show that anthropogenic VOCs (AVOC) enhance the mean daily maximum 8 h average ozone in Pasadena by 13 ppb, whereas biogenic VOCs (BVOCs) contribute 9.4 ppb. Of the ozone influenced by AVOCs, VCPs represent the largest fraction at 45 %, while cooking and fossil fuel VOCs are comparable at 26 % and 29 %, respectively. NOx sensitivity analyses along trajectory paths indicate that the photochemical regime of ozone varies spatially and temporally. The modeled ozone response is primarily NOx-saturated across the dense urban core and during peak ozone production in Pasadena. Lowering the inventory emissions of NOx by 25 % moves Pasadena to NOx-limited chemistry during afternoon hours and shrinks the spatial extent of NOx saturation towards downtown LA. Further sensitivity analyses show that using VOCs represented by a separate state inventory requires steeper NOx reductions to transition to NOx sensitivity, further suggesting that accurately representing VOC reactivity in inventories is critical to determining the effectiveness of future NOx reduction policies. [ABSTRACT FROM AUTHOR]

Published

2025

3. Early Season 2023 Wildfires Generated Record‐Breaking Surface Ozone Anomalies Across the U.S. Upper Midwest.

Author

Cooper, Owen R., Chang, Kai‐Lan, Bates, Kelvin, Brown, Steven S., Chace, Wyndom S., Coggon, Matthew M., Gorchov Negron, Alan M., Middlebrook, Ann M., Peischl, Jeff, Piasecki, Alison, Schafer, Nell, Stockwell, Chelsea E., Wang, Siyuan, Warneke, Carsten, Zuraski, Kristen, Miyazaki, Kazuyuki, Payne, Vivienne H., Pennington, Elyse A., Worden, John R., and Bowman, Kevin W.

Subjects

SMOKE plumes, SURFACE of the earth, AIR pollution, PARTICULATE matter, GREENHOUSE gases, TRACE gases

Abstract

During summer 2023 Canada experienced its most intense wildfire season on record. Smoke plumes from these fires advected across the United States (U.S.) Upper Midwest, producing regional scale surface enhancements of PM2.5 and ozone, as recorded by the U.S. surface monitoring network. These events are notable because they occurred early in the fire season (May 15‐June 30), and they produced the highest regional‐scale surface ozone levels ever recorded across the northern tier of the U.S. during early (May–June) or late (July‐August) summer. Specifically, the Upper Midwest 50th ozone percentile was greater than in any other year since 1995, when the ozone monitoring network had sufficient coverage to assess regional‐scale ozone levels; the 90th percentile was the highest since 2002. Satellite and aircraft measurements demonstrate the availability of ozone precursors and ozone production within the smoke plumes. Plain Language Summary: Ozone is a trace gas in the atmosphere that acts as an important greenhouse gas, and high concentrations near Earth's surface are a form of air pollution, detrimental to human health and vegetation productivity. Ozone is formed by sunlight reacting with precursor gases, such as those emitted by fossil fuel combustion. Wildfires are also an important source of ozone precursor gases. During summer 2023 Canada experienced its most intense wildfire season on record. Smoke from these fires impacted the U.S. Upper Midwest during May–June 2023, leading to regional scale surface enhancements of fine particulate matter and ozone. These unusual early season fires produced the highest regional‐scale surface ozone levels ever recorded across the northern U.S. Mid‐latitude wildfires have increased as the planet warms, and their frequency is expected to increase further with continued climate change. This analysis suggests that extreme ozone pollution episodes associated with wildfires could also increase in the future. Key Points: During summer 2023 Canada experienced its most intense wildfire season on recordSmoke from these fires impacted the United States (U.S.) Upper Midwest during May–June, leading to regional scale surface enhancements of PM2.5 and ozoneThese unusual early season fires produced the highest regional‐scale surface ozone levels ever recorded across the northern United States [ABSTRACT FROM AUTHOR]

Published

2024

4. O3 Sensitivity to NOx and VOC During RECAP-CA: Implication for Emissions Control Strategies

Author

Wu, Shenglun, primary, Alaimo, Christopher P., additional, Zhao, Yusheng, additional, Green, Peter G., additional, Young, Thomas M., additional, Liu, Shang, additional, Kuwayama, Toshihiro, additional, Coggon, Matthew M., additional, Stockwell, Chelsea E., additional, Xu, Lu, additional, Warneke, Carsten, additional, Gilman, Jessica B., additional, Robinson, Michael A., additional, Veres, Patrick R., additional, Neuman, J. Andrew, additional, and Kleeman, Michael J., additional

Published

2024

5. Stratocumulus Cloud Clearings and Notable Thermodynamic and Aerosol Contrasts across the Clear–Cloudy Interface

Author

Crosbie, Ewan, Wang, Zhen, Sorooshian, Armin, Chuang, Patrick Y, Craven, Jill S, Coggon, Matthew M, Brunke, Michael, Zeng, Xubin, Jonsson, Haflidi, Woods, Roy K, Flagan, Richard C, and Seinfeld, John H

Subjects

Aircraft observations, Atm/Ocean Structure/ Phenomena, North Pacific Ocean, Thermodynamics, Physical Meteorology and Climatology, Cloud cover, Observational techniques and algorithms, Aerosols, Boundary layer, Geographic location/entity, Atmospheric Sciences, Meteorology & Atmospheric Sciences

Abstract

Abstract Data from three research flights, conducted over water near the California coast, are used to investigate the boundary between stratocumulus cloud decks and clearings of different sizes. Large clearings exhibit a diurnal cycle with growth during the day and contraction overnight and a multiday life cycle that can include oscillations between growth and decay, whereas a small coastal clearing was observed to be locally confined with a subdiurnal lifetime. Subcloud aerosol characteristics are similar on both sides of the clear–cloudy boundary in the three cases, while meteorological properties exhibit subtle, yet important, gradients, implying that dynamics, and not microphysics, is the primary driver for the clearing characteristics. Transects, made at multiple levels across the cloud boundary during one flight, highlight the importance of microscale (~1 km) structure in thermodynamic properties near the cloud edge, suggesting that dynamic forcing at length scales comparable to the convective eddy scale may be influential to the larger-scale characteristics of the clearing. These results have implications for modeling and observational studies of marine boundary layer clouds, especially in relation to aerosol–cloud interactions and scales of variability responsible for the evolution of stratocumulus clearings.

Published

2016

6. Evolution of Reactive Organic Compounds and Their Potential Health Risk in Wildfire Smoke

Author

Pye, Havala O. T., Xu, Lu, Henderson, Barron H., Pagonis, Demetrios, Campuzano-Jost, Pedro, Guo, Hongyu, Jimenez, Jose L., Allen, Christine, Skipper, T. Nash, Halliday, Hannah S., Murphy, Benjamin N., D’Ambro, Emma L., Wennberg, Paul O., Place, Bryan K., Wiser, Forwood C., McNeill, V. Faye, Apel, Eric C., Blake, Donald R., Coggon, Matthew M., Crounse, John D., Gilman, Jessica B., Gkatzelis, Georgios I., Hanisco, Thomas F., Huey, L. Gregory, Katich, Joseph M., Lamplugh, Aaron, Lindaas, Jakob, Peischl, Jeff, St Clair, Jason M., Warneke, Carsten, Wolfe, Glenn M., and Womack, Caroline

Abstract

Wildfires are an increasing source of emissions into the air, with health effects modulated by the abundance and toxicity of individual species. In this work, we estimate reactive organic compounds (ROC) in western U.S. wildland forest fire smoke using a combination of observations from the 2019 Fire Influence on Regional to Global Environments and Air Quality (FIREX-AQ) field campaign and predictions from the Community Multiscale Air Quality (CMAQ) model. Standard emission inventory methods capture 40–45% of the estimated ROC mass emitted, with estimates of primary organic aerosol particularly low (5–8×). Downwind, gas-phase species abundances in molar units reflect the production of fragmentation products such as formaldehyde and methanol. Mass-based units emphasize larger compounds, which tend to be unidentified at an individual species level, are less volatile, and are typically not measured in the gas phase. Fire emissions are estimated to total 1250 ± 60 g·C of ROC per kg·C of CO, implying as much carbon is emitted as ROC as is emitted as CO. Particulate ROC has the potential to dominate the cancer and noncancer risk of long-term exposure to inhaled smoke, and better constraining these estimates will require information on the toxicity of particulate ROC from forest fires.

Published

2024

7. COVID-19 perturbation on US air quality and human health impact assessment

Author

He, Jian, primary, Harkins, Colin, additional, O'Dell, Katelyn, additional, Li, Meng, additional, Francoeur, Colby, additional, Aikin, Kenneth C, additional, Anenberg, Susan, additional, Baker, Barry, additional, Brown, Steven S, additional, Coggon, Matthew M, additional, Frost, Gregory J, additional, Gilman, Jessica B, additional, Kongdragunta, Shobha, additional, Lamplugh, Aaron, additional, Lyu, Congmeng, additional, Moon, Zachary, additional, Pierce, Bradley, additional, Schwantes, Rebecca H, additional, Stockwell, Chelsea E, additional, Warneke, Carsten, additional, Yang, Kai, additional, Nowlan, Caroline R, additional, González Abad, Gonzalo, additional, and McDonald, Brian C, additional

Published

2024

8. Contribution of Cooking Emissions to the Urban Volatile Organic Compounds in Las Vegas, NV

Author

Coggon, Matthew M., primary, Stockwell, Chelsea E., additional, Xu, Lu, additional, Peischl, Jeff, additional, Gilman, Jessica B., additional, Lamplugh, Aaron, additional, Bowman, Henry J., additional, Aikin, Kenneth, additional, Harkins, Colin, additional, Zhu, Qindan, additional, Schwantes, Rebecca H., additional, He, Jian, additional, Li, Meng, additional, Seltzer, Karl, additional, McDonald, Brian, additional, and Warneke, Carsten, additional

Published

2023

9. Supplementary material to "Contribution of Cooking Emissions to the Urban Volatile Organic Compounds in Las Vegas, NV"

Author

Coggon, Matthew M., primary, Stockwell, Chelsea E., additional, Xu, Lu, additional, Peischl, Jeff, additional, Gilman, Jessica B., additional, Lamplugh, Aaron, additional, Bowman, Henry J., additional, Aikin, Kenneth, additional, Harkins, Colin, additional, Zhu, Qindan, additional, Schwantes, Rebecca H., additional, He, Jian, additional, Li, Meng, additional, Seltzer, Karl, additional, McDonald, Brian, additional, and Warneke, Carsten, additional

Published

2023

10. Impact of Biomass Burning Organic Aerosol Volatility on Smoke Concentrations Downwind of Fires

Author

Pagonis, Demetrios, primary, Selimovic, Vanessa, additional, Campuzano-Jost, Pedro, additional, Guo, Hongyu, additional, Day, Douglas A., additional, Schueneman, Melinda K., additional, Nault, Benjamin A., additional, Coggon, Matthew M., additional, DiGangi, Joshua P., additional, Diskin, Glenn S., additional, Fortner, Edward C., additional, Gargulinski, Emily M., additional, Gkatzelis, Georgios I., additional, Hair, Johnathan W., additional, Herndon, Scott C., additional, Holmes, Christopher D., additional, Katich, Joseph M., additional, Nowak, John B., additional, Perring, Anne E., additional, Saide, Pablo, additional, Shingler, Taylor J., additional, Soja, Amber J., additional, Thapa, Laura H., additional, Warneke, Carsten, additional, Wiggins, Elizabeth B., additional, Wisthaler, Armin, additional, Yacovitch, Tara I., additional, Yokelson, Robert J., additional, and Jimenez, Jose L., additional

Published

2023

11. Emission Factors for Crop Residue and Prescribed Fires in the Eastern US During FIREX‐AQ

Author

Travis, Katherine R., primary, Crawford, James. H., additional, Soja, Amber J., additional, Gargulinski, Emily M., additional, Moore, Richard H., additional, Wiggins, Elizabeth B., additional, Diskin, Glenn S., additional, DiGangi, Joshua P., additional, Nowak, John B., additional, Halliday, Hannah, additional, Yokelson, Robert J., additional, McCarty, Jessica L., additional, Simpson, Isobel J., additional, Blake, Donald R., additional, Meinardi, Simone, additional, Hornbrook, Rebecca S., additional, Apel, Eric C., additional, Hills, Alan J., additional, Warneke, Carsten, additional, Coggon, Matthew M., additional, Rollins, Andrew W., additional, Gilman, Jessica B., additional, Womack, Caroline C., additional, Robinson, Michael A., additional, Katich, Joseph M., additional, Peischl, Jeff, additional, Gkatzelis, Georgios I., additional, Bourgeois, Ilann, additional, Rickly, Pamela S., additional, Lamplugh, Aaron, additional, Dibb, Jack E., additional, Jimenez, Jose L., additional, Campuzano‐Jost, Pedro, additional, Day, Douglas A., additional, Guo, Hongyu, additional, Pagonis, Demetrios, additional, Wennberg, Paul O., additional, Crounse, John D., additional, Xu, Lu, additional, Hanisco, Thomas F., additional, Wolfe, Glenn M., additional, Liao, Jin, additional, St. Clair, Jason M., additional, Nault, Benjamin A., additional, Fried, Alan, additional, and Perring, Anne E., additional

Published

2023

12. Emissions and Atmospheric Chemistry of Furanoids from Biomass Burning: Insights from Laboratory to Atmospheric Observations.

Author

Romanias, Manolis N., Coggon, Matthew M., Al Ali, Fatima, Burkholder, James B., Dagaut, Philippe, Decker, Zachary, Warneke, Carsten, Stockwell, Chelsea E., Roberts, James M., Tomas, Alexandre, Houzel, Nicolas, Coeur, Cecile, and Brown, Steven S.

Published

2024

13. Contribution of cooking emissions to the urban volatile organic compounds in Las Vegas, NV.

Author

Coggon, Matthew M., Stockwell, Chelsea E., Xu, Lu, Peischl, Jeff, Gilman, Jessica B., Lamplugh, Aaron, Bowman, Henry J., Aikin, Kenneth, Harkins, Colin, Zhu, Qindan, Schwantes, Rebecca H., He, Jian, Li, Meng, Seltzer, Karl, McDonald, Brian, and Warneke, Carsten

Subjects

TIME-of-flight mass spectrometers, MATRIX decomposition, EMISSION inventories, COOKING, FOSSIL fuels, VOLATILE organic compounds

Abstract

Cooking is a source of volatile organic compounds (VOCs), which degrade air quality. Cooking VOCs have been investigated in laboratory and indoor studies, but the contribution of cooking to the spatial and temporal variability in urban VOCs is uncertain. In this study, a proton-transfer-reaction time-of-flight mass spectrometer (PTR-ToF-MS) is used to identify and quantify cooking emission in Las Vegas, NV, with supplemental data from Los Angeles, CA, and Boulder, CO. Mobile laboratory data show that long-chain aldehydes, such as octanal and nonanal, are significantly enhanced in restaurant plumes and regionally enhanced in areas of Las Vegas with high restaurant densities. Correlation analyses show that long-chain fatty acids are also associated with cooking emissions and that the relative VOC enhancements observed in regions with dense restaurant activity are very similar to the distribution of VOCs observed in laboratory cooking studies. Positive matrix factorization (PMF) is used to quantify cooking emissions from ground site measurements and to compare the magnitude of cooking with other important urban sources, such as volatile chemical products and fossil fuel emissions. PMF shows that cooking may account for as much as 20 % of the total anthropogenic VOC emissions observed by PTR-ToF-MS. In contrast, emissions estimated from county-level inventories report that cooking accounts for less than 1 % of urban VOCs. Current emissions inventories do not fully account for the emission rates of long-chain aldehydes reported here; thus, further work is likely needed to improve model representations of important aldehyde sources, such as commercial and residential cooking. [ABSTRACT FROM AUTHOR]

Published

2024

14. Fuel-Type Independent Parameterization of Volatile Organic Compound Emissions from Western US Wildfires

Author

Sekimoto, Kanako, primary, Coggon, Matthew M., additional, Gkatzelis, Georgios I., additional, Stockwell, Chelsea E., additional, Peischl, Jeff, additional, Soja, Amber J., additional, and Warneke, Carsten, additional

Published

2023

15. Sensitivity of northeastern US surface ozone predictions to the representation of atmospheric chemistry in the Community Regional Atmospheric Chemistry Multiphase Mechanism (CRACMMv1.0)

Author

Place, Bryan K., primary, Hutzell, William T., additional, Appel, K. Wyat, additional, Farrell, Sara, additional, Valin, Lukas, additional, Murphy, Benjamin N., additional, Seltzer, Karl M., additional, Sarwar, Golam, additional, Allen, Christine, additional, Piletic, Ivan R., additional, D'Ambro, Emma L., additional, Saunders, Emily, additional, Simon, Heather, additional, Torres-Vasquez, Ana, additional, Pleim, Jonathan, additional, Schwantes, Rebecca H., additional, Coggon, Matthew M., additional, Xu, Lu, additional, Stockwell, William R., additional, and Pye, Havala O. T., additional

Published

2023

16. Secondary Organic Aerosol Formation from Volatile Chemical Product Emissions: Model Parameters and Contributions to Anthropogenic Aerosol

Author

Sasidharan, Sreejith, primary, He, Yicong, additional, Akherati, Ali, additional, Li, Qi, additional, Li, Weihua, additional, Cocker, David, additional, McDonald, Brian C., additional, Coggon, Matthew M., additional, Seltzer, Karl M., additional, Pye, Havala O. T., additional, Pierce, Jeffrey R., additional, and Jathar, Shantanu H., additional

Published

2023

17. Evolution of organic carbon in the laboratory oxidation of biomass-burning emissions

Author

Nihill, Kevin J., primary, Coggon, Matthew M., additional, Lim, Christopher Y., additional, Koss, Abigail R., additional, Yuan, Bin, additional, Krechmer, Jordan E., additional, Sekimoto, Kanako, additional, Jimenez, Jose L., additional, de Gouw, Joost, additional, Cappa, Christopher D., additional, Heald, Colette L., additional, Warneke, Carsten, additional, and Kroll, Jesse H., additional

Published

2023

18. Evolution of organic carbon in the laboratory oxidation of biomass-burning emissions

Author

Nihill, Kevin J., Coggon, Matthew M., Lim, Christopher Y., Koss, Abigail R., Yuan, Bin, Krechmer, Jordan E., Sekimoto, Kanako, Jimenez, Jose L., Gouw, Joost, Cappa, Christopher D., Heald, Colette L., Warneke, Carsten, and Kroll, Jesse H.

Abstract

Biomass burning (BB) is a major source of reactive organic carbon into the atmosphere. Once in the atmosphere, these organic BB emissions, in both the gas and particle phases, are subject to atmospheric oxidation, though the nature and impact of the chemical transformations are not currently well constrained. Here we describe experiments carried out as part of the FIREX FireLab campaign, in which smoke from the combustion of fuels typical of the western United States was sampled into an environmental chamber and exposed to high concentrations of OH, to simulate the equivalent of up to 2 d of atmospheric oxidation. The evolution of the organic mixture was monitored using three real-time time-of-flight mass spectrometric instruments (a proton transfer reaction mass spectrometer, an iodide chemical ionization mass spectrometer, and an aerosol mass spectrometer), providing measurements of both individual species and ensemble properties of the mixture. The combined measurements from these instruments achieve a reasonable degree of carbon closure (within 15 %–35 %), indicating that most of the reactive organic carbon is measured by these instruments. Consistent with our previous studies of the oxidation of individual organic species, atmospheric oxidation of the complex organic mixture leads to the formation of species that on average are smaller and more oxidized than those in the unoxidized emissions. In addition, the comparison of mass spectra from the different fuels indicates that the oxidative evolution of BB emissions proceeds largely independent of fuel type, with different fresh smoke mixtures ultimately converging into a common, aged distribution of gas-phase compounds. This distribution is characterized by high concentrations of several small, volatile oxygenates, formed from fragmentation reactions, as well as a complex pool of many minor oxidized species and secondary organic aerosol, likely formed via functionalization processes.

Published

2023

19. Parameterizations of US wildfire and prescribed fire emission ratios and emission factors based on FIREX-AQ aircraft measurements

Author

Gkatzelis, Georgios I., Coggon, Matthew M., Stockwell, Chelsea E., Hornbrook, Rebecca S., Allen, Hannah, Apel, Eric C., Ball, Katherine, Bela, Megan M., Blake, Donald R., Bourgeois, Ilann, Brown, Steven S., Campuzano-Jost, Pedro, Clair, Jason M., Crawford, James H., Crounse, John D., Day, Douglas A., DiGangi, Joshua, Diskin, Glenn, Fried, Alan, Gilman, Jessica, Guo, Hongyu, Hair, Johnathan W., Halliday, Hannah A., Hanisco, Thomas F., Hannun, Reem, Hills, Alan, Huey, Gregory, Jimenez, Jose L., Katich, Joseph M., Lamplugh, Aaron, Lee, Young Ro, Liao, Jin, Lindaas, Jakob, McKeen, Stuart A., Mikoviny, Tomas, Nault, Benjamin A., Neuman, James A., Nowak, John B., Pagonis, Demetrios, Peischl, Jeff, Perring, Anne E., Piel, Felix, Rickly, Pamela S., Robinson, Michael A., Rollins, Andrew W., Ryerson, Thomas B., Schueneman, Melinda K., Schwantes, Rebecca H., Schwarz, Joshua P., Sekimoto, Kanako, Selimovic, Vanessa, Shingler, Taylor, Tanner, David J., Tomsche, Laura, Vasquez, Krystal, Veres, Patrick R., Washenfelder, Rebecca, Weibring, Petter, Wennberg, Paul O., Wisthaler, Armin, Wolfe, Glenn, Womack, Caroline, Xu, Lu, Yokelson, Robert, and Warneke, Carsten

Abstract

Extensive airborne measurements of non-methane organic gases (NMOGs), methane, nitrogen oxides, reduced nitrogen-species, and aerosol emissions from US wild and prescribed fires were conducted during the 2019 NOAA/NASA Fire Influence on Regional to Global Environments and Air Quality campaign (FIREX-AQ). Here, we report the atmospheric enhancement ratios (ERs) and inferred emission factors (EFs) for compounds measured onboard the NASA DC-8 research aircraft for nine wildfires and one prescribed fire, which encompass a range of vegetation types. We use photochemical proxies to identify young smoke and reduce the effects of chemical degradation on our emissions calculations. ERs and EFs calculated from FIREX-AQ observations agree within a factor of 2 with values reported from previous laboratory and field studies for more than 80 % of the carbon- and nitrogen-containing species. Wildfire emissions are parameterized based on correlations of the sum of NMOGs with reactive nitrogen oxides (NOy) to modified combustion efficiency (MCE) as well as other chemical signatures indicative of flaming/smoldering combustion, including carbon monoxide (CO), nitrogen dioxide (NO2), and black carbon aerosol. The sum of primary NMOG EFs correlates to MCE with an R2 of 0.68 and a slope of -296 ± 51 g kg-1, consistent with previous studies. The sum of the NMOG mixing ratios correlates well with CO with an R2 of 0.98 and a slope of 137 ± 4 ppbv of NMOGs per ppmv of CO, demonstrating that primary NMOG emissions can be estimated from CO. Individual nitrogen-containing species correlate better with NO2, NOy, and black carbon than with CO. More than half of the NOy in fresh plumes is NO2 with an R2 of 0.95 and a ratio of NO2 to NOy of 0.55 ± 0.05 ppbv ppbv-1, highlighting that fast photochemistry had already occurred in the sampled fire plumes. The ratio of NOy to the sum of NMOGs follows trends observed in laboratory experiments and increases exponentially with MCE, due to increased emission of key nitrogen species and reduced emission of NMOGs at higher MCE during flaming combustion. These parameterizations will provide more accurate boundary conditions for modeling and satellite studies of fire plume chemistry and evolution to predict the downwind formation of secondary pollutants, including ozone and secondary organic aerosol.

Published

2023

20. Airborne Observations Constrain Heterogeneous Nitrogen and Halogen Chemistry on Tropospheric and Stratospheric Biomass Burning Aerosol.

Author

Decker, Zachary C. J., Novak, Gordon A., Aikin, Kenneth, Veres, Patrick R., Neuman, J. Andrew, Bourgeois, Ilann, Bui, T. Paul, Campuzano‐Jost, Pedro, Coggon, Matthew M., Day, Douglas A., DiGangi, Joshua P., Diskin, Glenn S., Dollner, Maximilian, Franchin, Alessandro, Fredrickson, Carley D., Froyd, Karl D., Gkatzelis, Georgios I., Guo, Hongyu, Hall, Samuel R., and Halliday, Hannah

Subjects

WILDFIRES, BIOMASS burning, STRATOSPHERIC chemistry, TROPOSPHERIC aerosols, TROPOSPHERIC chemistry, OZONE layer, OZONE layer depletion, STRATOSPHERIC aerosols

Abstract

Heterogeneous chemical cycles of pyrogenic nitrogen and halides influence tropospheric ozone and affect the stratosphere during extreme Pyrocumulonimbus (PyroCB) events. We report field‐derived N2O5 uptake coefficients, γ(N2O5), and ClNO2 yields, φ(ClNO2), from two aircraft campaigns observing fresh smoke in the lower and mid troposphere and processed/aged smoke in the upper troposphere and lower stratosphere (UTLS). Derived φ(ClNO2) varied across the full 0–1 range but was typically <0.5 and smallest in a PyroCB (<0.05). Derived γ(N2O5) was low in agricultural smoke (0.2–3.6 × 10−3), extremely low in mid‐tropospheric wildfire smoke (0.1 × 10−3), but larger in PyroCB processed smoke (0.7–5.0 × 10−3). Aged biomass burning aerosol in the UTLS had a higher γ(N2O5) of 17 × 10−3 that increased with sulfate and liquid water, but that was 1–2 orders of magnitude lower than values for aqueous sulfuric aerosol used in stratospheric models. Plain Language Summary: The injection of reactive material into Earth's atmosphere from fires affects atmospheric composition at regional and hemispheric scales. Reported stratospheric ozone depletion during extreme events, such as the 2020 Australian wildfires, illustrates one example of fire impacts and the role of heterogeneous (gas‐particle) processes. We report field quantification of rates and product yields from airborne observations of smoke. Extremely slow heterogeneous reaction rates on young smoke increase with transport and aging, but upper atmospheric values are still a factor of 10 slower than parameterizations used in stratospheric models. Heterogeneous production of ClNO2, a major lower atmospheric chlorine activation pathway, may be active on biomass burning aerosol in the upper atmosphere. Key Points: ClNO2 formation is active on biomass burning (BB) particles but decreases with transport to the upper troposphere and lower stratosphere (UTLS)N2O5 uptake coefficients are low on young BB smoke and increase with transport through a PyroCB and UTLS agingN2O5 uptake coefficients on aged BB particles in the UTLS are significantly lower than those used in model parameterizations [ABSTRACT FROM AUTHOR]

Published

2024

21. Identifying and correcting interferences to PTR-ToF-MS measurements of isoprene and other urban volatile organic compounds.

Author

Coggon, Matthew M., Stockwell, Chelsea E., Claflin, Megan S., Pfannerstill, Eva Y., Xu, Lu, Gilman, Jessica B., Marcantonio, Julia, Cao, Cong, Bates, Kelvin, Gkatzelis, Georgios I., Lamplugh, Aaron, Katz, Erin F., Arata, Caleb, Apel, Eric C., Hornbrook, Rebecca S., Piel, Felix, Majluf, Francesca, Blake, Donald R., Wisthaler, Armin, and Canagaratna, Manjula

Subjects

*VOLATILE organic compounds, *ISOPRENE, *TIME-of-flight mass spectrometry, *ACETALDEHYDE, *BIOGENIC amines, *PROTON transfer reactions, *CITIES & towns, *CYCLOALKANES

Abstract

Proton-transfer-reaction time-of-flight mass spectrometry (PTR-ToF-MS) is a technique commonly used to measure ambient volatile organic compounds (VOCs) in urban, rural, and remote environments. PTR-ToF-MS is known to produce artifacts from ion fragmentation, which complicates the interpretation and quantification of key atmospheric VOCs. This study evaluates the extent to which fragmentation and other ionization processes impact urban measurements of the PTR-ToF-MS ions typically assigned to isoprene (m/z 69, C 5 H 8 H +), acetaldehyde (m/z 45, CH 3 CHO +), and benzene (m/z 79, C 6 H 6 H +). Interferences from fragmentation are identified using gas chromatography (GC) pre-separation, and the impact of these interferences is quantified using ground-based and airborne measurements in a number of US cities, including Las Vegas, Los Angeles, New York City, and Detroit. In urban regions with low biogenic isoprene emissions (e.g., Las Vegas), fragmentation from higher-carbon aldehydes and cycloalkanes emitted from anthropogenic sources may contribute to m/z 69 by as much as 50 % during the day, while the majority of the signal at m/z 69 is attributed to fragmentation during the night. Interferences are a higher fraction of m/z 69 during airborne studies, which likely results from differences in the reactivity between isoprene and the interfering species along with the subsequent changes to the VOC mixture at higher altitudes. For other PTR masses, including m/z 45 and m/z 79, interferences are observed due to fragmentation and O 2+ ionization of VOCs typically used in solvents, which are becoming a more important source of anthropogenic VOCs in urban areas. We present methods to correct these interferences, which provide better agreement with GC measurements of isomer-specific molecules. These observations show the utility of deploying GC pre-separation for the interpretation PTR-ToF-MS spectra. [ABSTRACT FROM AUTHOR]

Published

2024

22. Parameterizations of US wildfire and prescribed fire emission ratios and emission factors based on FIREX-AQ aircraft measurements.

Author

Gkatzelis, Georgios I., Coggon, Matthew M., Stockwell, Chelsea E., Hornbrook, Rebecca S., Allen, Hannah, Apel, Eric C., Bela, Megan M., Blake, Donald R., Bourgeois, Ilann, Brown, Steven S., Campuzano-Jost, Pedro, St. Clair, Jason M., Crawford, James H., Crounse, John D., Day, Douglas A., DiGangi, Joshua P., Diskin, Glenn S., Fried, Alan, Gilman, Jessica B., and Guo, Hongyu

Subjects

PRESCRIBED burning, FLAME, FIRE management, COMBUSTION efficiency, WILDFIRES, CARBONACEOUS aerosols, AIR quality

Abstract

Extensive airborne measurements of non-methane organic gases (NMOGs), methane, nitrogen oxides, reduced nitrogen species, and aerosol emissions from US wild and prescribed fires were conducted during the 2019 NOAA/NASA Fire Influence on Regional to Global Environments and Air Quality campaign (FIREX-AQ). Here, we report the atmospheric enhancement ratios (ERs) and inferred emission factors (EFs) for compounds measured on board the NASA DC-8 research aircraft for nine wildfires and one prescribed fire, which encompass a range of vegetation types. We use photochemical proxies to identify young smoke and reduce the effects of chemical degradation on our emissions calculations. ERs and EFs calculated from FIREX-AQ observations agree within a factor of 2, with values reported from previous laboratory and field studies for more than 80 % of the carbon- and nitrogen-containing species. Wildfire emissions are parameterized based on correlations of the sum of NMOGs with reactive nitrogen oxides (NO y) to modified combustion efficiency (MCE) as well as other chemical signatures indicative of flaming/smoldering combustion, including carbon monoxide (CO), nitrogen dioxide (NO 2), and black carbon aerosol. The sum of primary NMOG EFs correlates to MCE with an R2 of 0.68 and a slope of - 296 ± 51 g kg -1 , consistent with previous studies. The sum of the NMOG mixing ratios correlates well with CO with an R2 of 0.98 and a slope of 137 ± 4 ppbv of NMOGs per parts per million by volume (ppmv) of CO, demonstrating that primary NMOG emissions can be estimated from CO. Individual nitrogen-containing species correlate better with NO 2 , NO y , and black carbon than with CO. More than half of the NO y in fresh plumes is NO 2 with an R2 of 0.95 and a ratio of NO 2 to NO y of 0.55 ± 0.05 ppbv ppbv -1 , highlighting that fast photochemistry had already occurred in the sampled fire plumes. The ratio of NO y to the sum of NMOGs follows trends observed in laboratory experiments and increases exponentially with MCE, due to increased emission of key nitrogen species and reduced emission of NMOGs at higher MCE during flaming combustion. These parameterizations will provide more accurate boundary conditions for modeling and satellite studies of fire plume chemistry and evolution to predict the downwind formation of secondary pollutants, including ozone and secondary organic aerosol. [ABSTRACT FROM AUTHOR]

Published

2024

23. Constraining emissions of volatile organic compounds from western US wildfires with WE-CAN and FIREX-AQ airborne observations

Author

Jin, Lixu, primary, Permar, Wade, additional, Selimovic, Vanessa, additional, Ketcherside, Damien, additional, Yokelson, Robert J., additional, Hornbrook, Rebecca S., additional, Apel, Eric C., additional, Ku, I-Ting, additional, Collett Jr., Jeffrey L., additional, Sullivan, Amy P., additional, Jaffe, Daniel A., additional, Pierce, Jeffrey R., additional, Fried, Alan, additional, Coggon, Matthew M., additional, Gkatzelis, Georgios I., additional, Warneke, Carsten, additional, Fischer, Emily V., additional, and Hu, Lu, additional

Published

2023

24. Linking gas, particulate, and toxic endpoints to air emissions in the Community Regional Atmospheric Chemistry Multiphase Mechanism (CRACMM)

Author

Pye, Havala O. T., primary, Place, Bryan K., additional, Murphy, Benjamin N., additional, Seltzer, Karl M., additional, D'Ambro, Emma L., additional, Allen, Christine, additional, Piletic, Ivan R., additional, Farrell, Sara, additional, Schwantes, Rebecca H., additional, Coggon, Matthew M., additional, Saunders, Emily, additional, Xu, Lu, additional, Sarwar, Golam, additional, Hutzell, William T., additional, Foley, Kristen M., additional, Pouliot, George, additional, Bash, Jesse, additional, and Stockwell, William R., additional

Published

2023

25. Sensitivity of Northeast U.S. surface ozone predictions to the representation of atmospheric chemistry in CRACMMv1.0

Author

Place, Bryan K., primary, Hutzell, William T., additional, Appel, K. Wyat, additional, Farrell, Sara, additional, Valin, Lukas, additional, Murphy, Benjamin N., additional, Seltzer, Karl M., additional, Sarwar, Golam, additional, Allen, Christine, additional, Piletic, Ivan R., additional, D'Ambro, Emma L., additional, Saunders, Emily, additional, Simon, Heather, additional, Torres-Vasquez, Ana, additional, Pleim, Jonathan, additional, Schwantes, Rebecca H., additional, Coggon, Matthew M., additional, Xu, Lu, additional, Stockwell, William R., additional, and Pye, Havala O. T., additional

Published

2023

26. Supplementary material to "Sensitivity of Northeast U.S. surface ozone predictions to the representation of atmospheric chemistry in CRACMMv1.0"

Author

Place, Bryan K., primary, Hutzell, William T., additional, Appel, K. Wyat, additional, Farrell, Sara, additional, Valin, Lukas, additional, Murphy, Benjamin N., additional, Seltzer, Karl M., additional, Sarwar, Golam, additional, Allen, Christine, additional, Piletic, Ivan R., additional, D'Ambro, Emma L., additional, Saunders, Emily, additional, Simon, Heather, additional, Torres-Vasquez, Ana, additional, Pleim, Jonathan, additional, Schwantes, Rebecca H., additional, Coggon, Matthew M., additional, Xu, Lu, additional, Stockwell, William R., additional, and Pye, Havala O. T., additional

Published

2023

27. Fire Influence on Regional to Global Environments and Air Quality (FIREX‐AQ)

Author

Warneke, Carsten, Schwarz, Joshua P., Washenfelder, Rebecca A., Wiggins, Elizabeth B., Moore, Richard H., Anderson, Bruce E., Jordan, Carolyn, Yacovitch, Tara I., Herndon, Scott C., Liu, Shang, Kuwayama, Toshihiro, Jaffe, Daniel, Dibb, Jack, Johnston, Nancy, Selimovic, Vanessa, Yokelson, Robert, Giles, David M., Holben, Brent N., Goloub, Philippe, Popovici, Ioana, Trainer, Michael, Kumar, Aditya, Pierce, R. Bradley, Kalashnikova, Olga, Fahey, David, Roberts, James, Gargulinski, Emily M., Peterson, David A., Ye, Xinxin, Thapa, Laura H., Saide, Pablo E., Fite, Charles H., Holmes, Christopher D., Wang, Siyuan, Frost, Gregory, Coggon, Matthew M., Decker, Zachary C. J., Stockwell, Chelsea E., Xu, Lu, Gkatzelis, Georgios, Aikin, Kenneth, Lefer, Barry, Kaspari, Jackson, Griffin, Debora, Zeng, Linghan, Al-Saad, Jassim, Weber, Rodney, Hastings, Meredith, Chai, Jiajue, Wolfe, Glenn M., Hanisco, Thomas F., Liao, Jin, Campuzano Jost, Pedro, Guo, Hongyu, Jimenez, Jose L., Crawford, James, Brown, Steven S., Brewer, Wm. Alan, Soja, Amber, and Seidel, Felix C.

Subjects

Atmospheric Science, Geophysics, Space and Planetary Science, Earth and Planetary Sciences (miscellaneous), ddc:550

Abstract

The NOAA/NASA Fire Influence on Regional to Global Environments and Air Quality (FIREX-AQ) experiment was a multi-agency, inter-disciplinary research effort to: (a) obtain detailed measurements of trace gas and aerosol emissions from wildfires and prescribed fires using aircraft, satellites and ground-based instruments, (b) make extensive suborbital remote sensing measurements of fire dynamics, (c) assess local, regional, and global modeling of fires, and (d) strengthen connections to observables on the ground such as fuels and fuel consumption and satellite products such as burned area and fire radiative power. From Boise, ID western wildfires were studied with the NASA DC-8 and two NOAA Twin Otter aircraft. The high-altitude NASA ER-2 was deployed from Palmdale, CA to observe some of these fires in conjunction with satellite overpasses and the other aircraft. Further research was conducted on three mobile laboratories and ground sites, and 17 different modeling forecast and analyses products for fire, fuels and air quality and climate implications. From Salina, KS the DC-8 investigated 87 smaller fires in the Southeast with remote and in-situ data collection. Sampling by all platforms was designed to measure emissions of trace gases and aerosols with multiple transects to capture the chemical transformation of these emissions and perform remote sensing observations of fire and smoke plumes under day and night conditions. The emissions were linked to fuels consumed and fire radiative power using orbital and suborbital remote sensing observations collected during overflights of the fires and smoke plumes and ground sampling of fuels.

Published

2023

28. Supplementary material to "Evolution of Organic Carbon in the Laboratory Oxidation of Biomass Burning Emissions"

Author

Nihill, Kevin John, primary, Coggon, Matthew M., additional, Lim, Christopher Y., additional, Koss, Abigail R., additional, Yuan, Bin, additional, Krechmer, Jordan E., additional, Sekimoto, Kanako, additional, Jimenez, Jose-Luis, additional, de Gouw, Joost, additional, Cappa, Christopher D., additional, Heald, Colette L., additional, Warneke, Carsten, additional, and Kroll, Jesse H., additional

Published

2023

29. Evolution of Organic Carbon in the Laboratory Oxidation of Biomass Burning Emissions

Author

Nihill, Kevin John, primary, Coggon, Matthew M., additional, Lim, Christopher Y., additional, Koss, Abigail R., additional, Yuan, Bin, additional, Krechmer, Jordan E., additional, Sekimoto, Kanako, additional, Jimenez, Jose-Luis, additional, de Gouw, Joost, additional, Cappa, Christopher D., additional, Heald, Colette L., additional, Warneke, Carsten, additional, and Kroll, Jesse H., additional

Published

2023

30. Influence of Wildfire on Urban Ozone: An Observationally Constrained Box Modeling Study at a Site in the Colorado Front Range

Author

Rickly, Pamela S., primary, Coggon, Matthew M., additional, Aikin, Kenneth C., additional, Alvarez, Raul J., additional, Baidar, Sunil, additional, Gilman, Jessica B., additional, Gkatzelis, Georgios I., additional, Harkins, Colin, additional, He, Jian, additional, Lamplugh, Aaron, additional, Langford, Andrew O., additional, McDonald, Brian C., additional, Peischl, Jeff, additional, Robinson, Michael A., additional, Rollins, Andrew W., additional, Schwantes, Rebecca H., additional, Senff, Christoph J., additional, Warneke, Carsten, additional, and Brown, Steven S., additional

Published

2023

31. Chemical ionization mass spectrometry utilizing ammonium ions (NH4+ CIMS) for measurements of organic compounds in the atmosphere

Author

Xu, Lu, primary, Coggon, Matthew M., additional, Stockwell, Chelsea E., additional, Gilman, Jessica B., additional, Robinson, Michael A., additional, Breitenlechner, Martin, additional, Lamplugh, Aaron, additional, Crounse, John D., additional, Wennberg, Paul O., additional, Neuman, J. Andrew, additional, Novak, Gordon A., additional, Veres, Patrick R., additional, Brown, Steven S., additional, and Warneke, Carsten, additional

Published

2022

32. Contribution of Cooking Emissions to the Urban Volatile Organic Compounds in Las Vegas, NV.

Author

Coggon, Matthew M., Stockwell, Chelsea E., Lu Xu, Peischl, Jeff, Gilman, Jessica B., Lamplugh, Aaron, Bowman, Henry J., Aikin, Kenneth, Harkins, Colin, Qindan Zhu, Schwantes, Rebecca H., Jian He, Meng Li, Seltzer, Karl, McDonald, Brian, and Warneke, Carsten

Abstract

Cooking is a source volatile organic compounds (VOCs) that degrades air quality. Cooking VOCs have been investigated in laboratory and indoor studies, but the contribution of cooking to the spatial and temporal variability of urban VOCs is uncertain. In this study, a proton-transfer27 reaction time-of-flight mass spectrometer (PTR-ToF-MS) is used to identify and quantify cooking emission in Las Vegas, NV with supplemental data from Los Angeles, CA and Boulder, CO. Mobile laboratory data show that long-chain aldehydes, such as octanal and nonanal, are significantly enhanced in restaurant plumes and regionally enhanced in areas of Las Vegas with high restaurant density. Correlation analyses show that long-chain fatty acids are also associated with cooking emissions and the relative VOC enhancements observed in regions with dense restaurant activity are very similar to the distribution of VOCs observed in laboratory cooking studies. Positive matrix factorization (PMF) is used to quantify cooking emissions from ground site measurements and compare the magnitude of cooking to other important urban sources, such as volatile chemical products and fossil fuel emissions. PMF shows that cooking may account for as much as 20% of the total anthropogenic VOC emissions observed by PTR-ToF-MS. In contrast, emissions estimated from county-level inventories report that cooking accounts for less than 1% of urban VOCs. Current emissions inventories do not fully account for the emission rates of chain aldehydes reported here and further work is likely needed to improve model representations of important aldehyde sources, such as commercial and residential cooking. [ABSTRACT FROM AUTHOR]

Published

2023

33. Multi-day photochemical evolution of organic aerosol from biomass burning emissionsElectronic supplementary information (ESI) available: Summary of environmental chamber data, additional SOM-TOMAS results and comparisons with measurements, and sensitivity simulation results. See DOI: https://doi.org/10.1039/d3ea00111c

Author

Dearden, Abraham, He, Yicong, Akherati, Ali, Lim, Christopher Y., Coggon, Matthew M., Koss, Abigail R., de Gouw, Joost, Warneke, Carsten, Yee, Lindsay D., Seinfeld, John H., Cappa, Christopher D., Kroll, Jesse H., Pierce, Jeffrey R., and Jathar, Shantanu H.

Abstract

Biomass burning is an important source of primary and secondary organic aerosol (POA, SOA, and together, OA) to the atmosphere. The photochemical evolution of biomass burning OA, especially over long photochemical ages, is highly complex and there are large uncertainties in how this evolution is represented in models. Recently, Lim et al.(2019) performed and reported on photooxidation experiments of biomass burning emissions using a small environmental chamber (∼150 L) to study the OA evolution over multiple equivalent days of photochemical aging. In this work, we use a kinetic, process-level model (SOM-TOMAS; Statistical Oxidation Model-TwO Moment Aerosol Sectional) to simulate the photochemical evolution of OA in 18 chamber experiments performed on emissions from 10 different fuels. A base version of the model was able to simulate the time-dependent evolution of the OA mass concentration and its oxygen-to-carbon ratio (O : C) at short photochemical ages (0.5 to 1 equivalent days). At longer photochemical ages (>1 equivalent day), the model exhibited poor skill in predicting the OA mass concentration and significantly underestimated the OA O : C. The modeled OA after several equivalent days of photochemical aging was slightly dominated by SOA (average of 57% across all experiments) with the remainder being POA (average of 43% across all experiments). Semi-volatile organic compounds, oxygenated aromatics, and heterocyclics accounted for the majority (89%, on average) of the SOA formed. Experimental artifacts (i.e., particle and vapor wall losses) were found to be much more important in influencing the OA evolution than other processes (i.e., dilution, heterogeneous chemistry, and oligomerization reactions). Adjustments to the kinetic model seemed to improve model performance only marginally indicating that the model was missing precursors, chemical pathways, or both, especially to explain the observed enhancement in OA mass and O : C over longer photochemical ages. While far from ideal, this work contributes to a process-level understanding of biomass burning OA that is relevant for its extended evolution at regional and global scales.

Published

2024

34. Supplementary material to "Constraining emissions of volatile organic compounds from western US wildfires with WE-CAN and FIREX-AQ airborne observations"

Author

Jin, Lixu, primary, Permar, Wade, additional, Selimovic, Vanessa, additional, Ketcherside, Damien, additional, Yokelson, Robert J., additional, Hornbrook, Rebecca S., additional, Apel, Eric C., additional, Ku, I-Ting, additional, Collett Jr., Jeffrey L., additional, Sullivan, Amy P., additional, Jaffe, Daniel A., additional, Pierce, Jeffrey R., additional, Fried, Alan, additional, Coggon, Matthew M., additional, Gkatzelis, Georgios I., additional, Warneke, Carsten, additional, Fischer, Emily V., additional, and Hu, Lu, additional

Published

2022

35. Constraining emissions of volatile organic compounds from western US wildfires with WE-CAN and FIREX-AQ airborne observations

Author

Jin, Lixu, primary, Permar, Wade, additional, Selimovic, Vanessa, additional, Ketcherside, Damien, additional, Yokelson, Robert J., additional, Hornbrook, Rebecca S., additional, Apel, Eric C., additional, Ku, I-Ting, additional, Collett Jr., Jeffrey L., additional, Sullivan, Amy P., additional, Jaffe, Daniel A., additional, Pierce, Jeffrey R., additional, Fried, Alan, additional, Coggon, Matthew M., additional, Gkatzelis, Georgios I., additional, Warneke, Carsten, additional, Fischer, Emily V., additional, and Hu, Lu, additional

Published

2022

36. Supplementary material to "Linking gas, particulate, and toxic endpoints to air emissions in the Community Regional Atmospheric Chemistry Multiphase Mechanism (CRACMM) version 1.0"

Author

Pye, Havala O. T., primary, Place, Bryan K., additional, Murphy, Benjamin N., additional, Seltzer, Karl M., additional, D'Ambro, Emma L., additional, Allen, Christine, additional, Piletic, Ivan R., additional, Farrell, Sara, additional, Schwantes, Rebecca H., additional, Coggon, Matthew M., additional, Saunders, Emily, additional, Xu, Lu, additional, Sarwar, Golam, additional, Hutzell, William T., additional, Foley, Kristen M., additional, Pouliot, George, additional, Bash, Jesse, additional, and Stockwell, William R., additional

Published

2022

37. Linking gas, particulate, and toxic endpoints to air emissions in the Community Regional Atmospheric Chemistry Multiphase Mechanism (CRACMM) version 1.0

Author

Pye, Havala O. T., primary, Place, Bryan K., additional, Murphy, Benjamin N., additional, Seltzer, Karl M., additional, D'Ambro, Emma L., additional, Allen, Christine, additional, Piletic, Ivan R., additional, Farrell, Sara, additional, Schwantes, Rebecca H., additional, Coggon, Matthew M., additional, Saunders, Emily, additional, Xu, Lu, additional, Sarwar, Golam, additional, Hutzell, William T., additional, Foley, Kristen M., additional, Pouliot, George, additional, Bash, Jesse, additional, and Stockwell, William R., additional

Published

2022

38. Aerosol size distribution changes in FIREX-AQ biomass burning plumes: the impact of plume concentration on coagulation and OA condensation/evaporation

Author

June, Nicole A., primary, Hodshire, Anna L., additional, Wiggins, Elizabeth B., additional, Winstead, Edward L., additional, Robinson, Claire E., additional, Thornhill, K. Lee, additional, Sanchez, Kevin J., additional, Moore, Richard H., additional, Pagonis, Demetrios, additional, Guo, Hongyu, additional, Campuzano-Jost, Pedro, additional, Jimenez, Jose L., additional, Coggon, Matthew M., additional, Dean-Day, Jonathan M., additional, Bui, T. Paul, additional, Peischl, Jeff, additional, Yokelson, Robert J., additional, Alvarado, Matthew J., additional, Kreidenweis, Sonia M., additional, Jathar, Shantanu H., additional, and Pierce, Jeffrey R., additional

Published

2022

39. Identifying and correcting interferences to PTR-ToF-MS measurements of isoprene and other urban volatile organic compounds.

Author

Coggon, Matthew M., Stockwell, Chelsea E., Claflin, Megan S., Pfannerstill, Eva Y., Xu Lu, Gilman, Jessica B., Marcantonio, Julia, Cong Cao, Bates, Kelvin, Gkatzelis, Georgios I., Lamplugh, Aaron, Katz, Erin F., Arata, Caleb, Apel, Eric C., Hornbook, Rebecca S., Piel, Felix, Majluf, Francesca, Blake, Donald R., Wisthaler, Armin, and Canagaratna, Manjula

Subjects

*VOLATILE organic compounds, *ISOPRENE, *TIME-of-flight mass spectrometry, *ACETALDEHYDE, *BIOGENIC amines, *PROTON transfer reactions, *CITIES & towns, *CYCLOALKANES

Abstract

Proton-transfer-reaction time-of-flight mass spectrometry (PTR-ToF-MS) is a technique commonly used to measure ambient volatile organic compounds (VOCs) in urban, rural, and remote environments. PTR-ToF-MS is known to produce artifacts from ion fragmentation, which complicates the interpretation and quantification of key atmospheric VOCs. This study evaluates the extent to which fragmentation and other ionization processes impacts urban measurements of the PTR-ToF-MS ions typically assigned to isoprene (m/z 69, C5H8H+), acetaldehyde (m/z 45, CH3CHO+), and benzene (m/z 79, C6H6H+). Interferences from fragmentation are identified using gas-chromatography (GC) pre-separation and the impact of these interferences are quantified using ground-based and airborne measurements in a number of US cities, including Las Vegas, Los Angeles, New York City, and Detroit. In urban regions with low biogenic isoprene emissions (e.g., Las Vegas), fragmentation from higher carbon aldehydes and cycloalkanes emitted from anthropogenic sources may contribute to m/z 69 by as much as 50% during the day, while the majority of the signal at m/z 69 is attributed to fragmentation during the night. Interferences are a higher fraction of m/z 69 during airborne studies, which likely results from differences in the reactivity between isoprene and the interfering species along with the subsequent changes to the VOC mixture at higher altitudes. For other PTR masses, including m/z 45 and m/z 79, interferences are observed due to the fragmentation and secondary ionization of VOCs typically used in solvents, which are becoming a more important source of anthropogenic VOCs in urban areas. We present methods to correct these interferences, which provide better agreement with GC measurements of isomer specific molecules. These observations show the utility of deploying GC pre-separation for the interpretation PTR-ToF-MS spectra. [ABSTRACT FROM AUTHOR]

Published

2023

40. Science of the Environmental Chamber

Author

Schwantes, Rebecca H., primary, McVay, Renee C., additional, Zhang, Xuan, additional, Coggon, Matthew M., additional, Lignell, Hanna, additional, Flagan, Richard C., additional, Wennberg, Paul O., additional, and Seinfeld, John H., additional

Published

2017

41. Comparison of airborne measurements of NO, NO2, HONO, NOy, and CO during FIREX-AQ

Author

Bourgeois, Ilann, primary, Peischl, Jeff, additional, Neuman, J. Andrew, additional, Brown, Steven S., additional, Allen, Hannah M., additional, Campuzano-Jost, Pedro, additional, Coggon, Matthew M., additional, DiGangi, Joshua P., additional, Diskin, Glenn S., additional, Gilman, Jessica B., additional, Gkatzelis, Georgios I., additional, Guo, Hongyu, additional, Halliday, Hannah A., additional, Hanisco, Thomas F., additional, Holmes, Christopher D., additional, Huey, L. Gregory, additional, Jimenez, Jose L., additional, Lamplugh, Aaron D., additional, Lee, Young Ro, additional, Lindaas, Jakob, additional, Moore, Richard H., additional, Nault, Benjamin A., additional, Nowak, John B., additional, Pagonis, Demetrios, additional, Rickly, Pamela S., additional, Robinson, Michael A., additional, Rollins, Andrew W., additional, Selimovic, Vanessa, additional, St. Clair, Jason M., additional, Tanner, David, additional, Vasquez, Krystal T., additional, Veres, Patrick R., additional, Warneke, Carsten, additional, Wennberg, Paul O., additional, Washenfelder, Rebecca A., additional, Wiggins, Elizabeth B., additional, Womack, Caroline C., additional, Xu, Lu, additional, Zarzana, Kyle J., additional, and Ryerson, Thomas B., additional

Published

2022

42. Supplementary material to "A Chemical Ionization Mass Spectrometry Utilizing Ammonium Ions (NH4+ CIMS) for Measurements of Organic Compounds in the Atmosphere"

Author

Xu, Lu, primary, Coggon, Matthew M., additional, Stockwell, Chelsea E., additional, Gilman, Jessica B., additional, Robinson, Michael A., additional, Breitenlechner, Martin, additional, Lamplugh, Aaron, additional, Neuman, J. Andrew, additional, Novak, Gordon A., additional, Veres, Patrick R., additional, Brown, Steven S., additional, and Warneke, Carsten, additional

Published

2022

43. A Chemical Ionization Mass Spectrometry Utilizing Ammonium Ions (NH4+ CIMS) for Measurements of Organic Compounds in the Atmosphere

Author

Xu, Lu, primary, Coggon, Matthew M., additional, Stockwell, Chelsea E., additional, Gilman, Jessica B., additional, Robinson, Michael A., additional, Breitenlechner, Martin, additional, Lamplugh, Aaron, additional, Neuman, J. Andrew, additional, Novak, Gordon A., additional, Veres, Patrick R., additional, Brown, Steven S., additional, and Warneke, Carsten, additional

Published

2022

44. OH chemistry of non-methane organic gases (NMOGs) emitted from laboratory and ambient biomass burning smoke: evaluating the influence of furans and oxygenated aromatics on ozone and secondary NMOG formation

Author

Massachusetts Institute of Technology. Department of Civil and Environmental Engineering, Coggon, Matthew M., Lim, Christopher Yung-Ta, Koss, Abigail R., Sekimoto, Kanako, Yuan, Bin, Gilman, Jessica B., Hagan, David Henry, Selimovic, Vanessa, Zarzana, Kyle J., Brown, Steven S., Roberts, James M., Müller, Markus, Yokelson, Robert, Wisthaler, Armin, Krechmer, Jordan E., Jimenez, Jose L., Cappa, Christopher, Kroll, Jesse, de Gouw, Joost, Warneke, Carsten, Massachusetts Institute of Technology. Department of Civil and Environmental Engineering, Coggon, Matthew M., Lim, Christopher Yung-Ta, Koss, Abigail R., Sekimoto, Kanako, Yuan, Bin, Gilman, Jessica B., Hagan, David Henry, Selimovic, Vanessa, Zarzana, Kyle J., Brown, Steven S., Roberts, James M., Müller, Markus, Yokelson, Robert, Wisthaler, Armin, Krechmer, Jordan E., Jimenez, Jose L., Cappa, Christopher, Kroll, Jesse, de Gouw, Joost, and Warneke, Carsten

Abstract

© Author(s) 2019. Chamber oxidation experiments conducted at the Fire Sciences Laboratory in 2016 are evaluated to identify important chemical processes contributing to the hydroxy radical (OH) chemistry of biomass burning non-methane organic gases (NMOGs). Based on the decay of primary carbon measured by proton transfer reaction time-of-flight mass spectrometry (PTR-ToF-MS), it is confirmed that furans and oxygenated aromatics are among the NMOGs emitted from western United States fuel types with the highest reactivities towards OH. The oxidation processes and formation of secondary NMOG masses measured by PTR-ToF-MS and iodide-clustering time-of-flight chemical ionization mass spectrometry (I-CIMS) is interpreted using a box model employing a modified version of the Master Chemical Mechanism (v. 3.3.1) that includes the OH oxidation of furan, 2-methylfuran, 2,5-dimethylfuran, furfural, 5-methylfurfural, and guaiacol. The model supports the assignment of major PTR-ToF-MS and I-CIMS signals to a series of anhydrides and hydroxy furanones formed primarily through furan chemistry. This mechanism is applied to a Lagrangian box model used previously to model a real biomass burning plume. The customized mechanism reproduces the decay of furans and oxygenated aromatics and the formation of secondary NMOGs, such as maleic anhydride. Based on model simulations conducted with and without furans, it is estimated that furans contributed up to 10% of ozone and over 90% of maleic anhydride formed within the first 4h of oxidation. It is shown that maleic anhydride is present in a biomass burning plume transported over several days, which demonstrates the utility of anhydrides as markers for aged biomass burning plumes.

Published

2022

45. Supplementary material to &quot;Aerosol size distribution changes in FIREX-AQ biomass burning plumes: the impact of plume concentration on coagulation and OA condensation/evaporation&quot;

Author

June, Nicole A., primary, Hodshire, Anna L., additional, Wiggins, Elizabeth B., additional, Winstead, Edward L., additional, Robinson, Claire E., additional, Thornhill, K. Lee, additional, Sanchez, Kevin J., additional, Moore, Richard H., additional, Pagonis, Demetrios, additional, Guo, Hongyu, additional, Campuzano-Jost, Pedro, additional, Jimenez, Jose L., additional, Coggon, Matthew M., additional, Dean-Day, Jonathan M., additional, Bui, T. Paul, additional, Peischl, Jeff, additional, Yokelson, Robert J., additional, Alvarado, Matthew J., additional, Kreidenweis, Sonia M., additional, Jathar, Shantanu H., additional, and Pierce, Jeffrey R., additional

Published

2022

46. Airborne Emission Rate Measurements Validate Remote Sensing Observations and Emission Inventories of Western U.S. Wildfires

Author

Stockwell, Chelsea E., primary, Bela, Megan M., additional, Coggon, Matthew M., additional, Gkatzelis, Georgios I., additional, Wiggins, Elizabeth, additional, Gargulinski, Emily M., additional, Shingler, Taylor, additional, Fenn, Marta, additional, Griffin, Debora, additional, Holmes, Christopher D., additional, Ye, Xinxin, additional, Saide, Pablo E., additional, Bourgeois, Ilann, additional, Peischl, Jeff, additional, Womack, Caroline C., additional, Washenfelder, Rebecca A., additional, Veres, Patrick R., additional, Neuman, J. Andrew, additional, Gilman, Jessica B., additional, Lamplugh, Aaron, additional, Schwantes, Rebecca H., additional, McKeen, Stuart A., additional, Wisthaler, Armin, additional, Piel, Felix, additional, Guo, Hongyu, additional, Campuzano-Jost, Pedro, additional, Jimenez, Jose L., additional, Fried, Alan, additional, Hanisco, Thomas F., additional, Huey, Lewis Gregory, additional, Perring, Anne, additional, Katich, Joseph M., additional, Diskin, Glenn S., additional, Nowak, John B., additional, Bui, T. Paul, additional, Halliday, Hannah S., additional, DiGangi, Joshua P., additional, Pereira, Gabriel, additional, James, Eric P., additional, Ahmadov, Ravan, additional, McLinden, Chris A., additional, Soja, Amber J., additional, Moore, Richard H., additional, Hair, Johnathan W., additional, and Warneke, Carsten, additional

Published

2022

47. Comparison of airborne measurements of NO, NO2, HONO, NOy and CO during FIREX-AQ

Author

Bourgeois, Ilann, Peischl, Jeff, Neuman, J. Andrew, Brown, Steven S., Allen, Hannah M., Campuzano-Jost, Pedro, Coggon, Matthew M., DiGangi, Joshua P., Diskin, Glenn S., Gilman, Jessica B., Gkatzelis, Georgios I., Guo, Hongyu, Halliday, Hannah, Hanisco, Thomas F., Holmes, Christopher D., Huey, L. Gregory, Jimenez, Jose L., Lamplugh, Aaron D., Lee, Young Ro, Lindaas, Jakob, Moore, Richard H., Nowak, John B., Pagonis, Demetrios, Rickly, Pamela S., Robinson, Michael A., Rollins, Andrew W., Selimovic, Vanessa, Clair, Jason M., Tanner, David, Vasquez, Krystal T., Veres, Patrick R., Warneke, Carsten, Wennberg, Paul O., Washenfelder, Rebecca A., Wiggins, Elizabeth B., Womack, Caroline C., Xu, Lu, Zarzana, Kyle J., and Ryerson, Thomas B.

Abstract

We present a comparison of fast-response instruments installed onboard the NASA DC-8 aircraft that measured nitrogen oxides (NO and NO2), nitrous acid (HONO), total reactive odd nitrogen (measured both as the total (NOy) and from the sum of individually measured species (SNOy)) and carbon monoxide (CO) in the troposphere during the 2019 Fire Influence on Regional to Global Environments and Air Quality (FIREX-AQ) campaign. By targeting smoke from summertime wildfires, prescribed fires and agricultural burns across the continental United States, FIREX-AQ provided a unique opportunity to investigate measurement accuracy in concentrated plumes where hundreds of species coexist. Here, we compare NO measurements by chemiluminescence (CL) and laser induced fluorescence (LIF); NO2 measurements by CL, LIF and cavity enhanced spectroscopy (CES); HONO measurements by CES and iodide-adduct chemical ionization mass spectrometry (CIMS); and CO measurements by tunable diode laser absorption spectrometry (TDLAS) and integrated cavity output spectroscopy (ICOS). Additionally, total NOy measurements using the CL instrument were compared with SNOy (= NO + NO2 + HONO + nitric acid (HNO3) + acyl peroxy nitrates (APNs) + submicron particulate nitrate (pNO3)). The aircraft instrument intercomparisons demonstrate the following: 1) NO measurements by CL and LIF agreed well within instrument uncertainties, but with potentially reduced time response for the CL instrument; 2) NO2 measurements by LIF and CES agreed well within instrument uncertainties, but CL NO2 was on average 10 % higher; 3) CES and CIMS HONO measurements were highly correlated in each fire plume transect, but the correlation slope of CES vs. CIMS for all 1 Hz data during FIREX-AQ was 1.8, which we attribute to a reduction in the CIMS sensitivity to HONO in high temperature environments; 4) NOy budget closure was demonstrated for all flights within the combined instrument uncertainties of 25 %. However, we used a fluid dynamic flow model to estimate that average pNO3 sampling fraction through the NOy inlet in smoke was variable from one flight to another and ranged between 0.36 and 0.99, meaning that approximately 0–24 % on average of the total measured NOy in smoke may have been unaccounted for and may be due to unmeasured species such as organic nitrates; 5) CO measurements by ICOS and TDLAS agreed well within combined instrument uncertainties, but with a systematic offset that averaged 2.87 ppbv; and 6) integrating smoke plumes followed by fitting the integrated values of each plume improved the correlation between independent measurements.

Published

2022

48. Sensitivity of Northeast U.S. surface ozone predictions to the representation of atmospheric chemistry in CRACMMv1.0.

Author

Place, Bryan K., Hutzell, William T., Appel, K. Wyat, Farrell, Sara, Valin, Lukas, Murphy, Benjamin N., Seltzer, Karl M., Sarwar, Golam, Allen, Christine, Piletic, Ivan R., D'Ambro, Emma L., Saunders, Emily, Simon, Heather, Torres-Vasquez, Ana, Pleim, Jonathan, Schwantes, Rebecca H., Coggon, Matthew M., Xu, Lu, Stockwell, William R., and Pye, Havala O. T.

Subjects

ATMOSPHERIC chemistry, OZONE, AIR quality, GREENHOUSE gas mitigation, AIR pollutants, FORECASTING, NITROGEN oxides

Abstract

Chemical mechanisms describe how emissions of gases and particles evolve in the atmosphere and are used within chemical transport models to evaluate past, current, and future air quality. Thus, a chemical mechanism must provide robust and accurate predictions of air pollutants if it is to be considered for use by regulatory bodies. In this work, we provide an initial evaluation of the Community Regional Atmospheric Chemical Multiphase Mechanism (CRACMMv1.0) by assessing CRACMMv1.0 predictions of surface ozone (O3) across the Northeast U.S. during the summer of 2018 within the Community Multiscale Air Quality (CMAQ) modeling system. CRACMMv1.0 O3 predictions of hourly and maximum daily 8-hour average (MDA8) ozone were lower than those estimated by the Regional Atmospheric Chemical Mechanism (RACM2_ae6), which better matched surface network observations in the Northeast US (RACM2_ae6 mean bias of +4.2 ppb for all hours and +4.3 ppb for MDA8; CRACMMv1.0 mean bias of +2.1 ppb for all hours and +2.7 ppb for MDA8). Box model calculations combined with results from CMAQ emission reduction simulations indicated high sensitivity of O3 to compounds with biogenic sources. In addition, these calculations indicated the differences between CRACMMv1.0 and RACM2_ae6 O3 predictions were largely explained by updates to the inorganic rate constants (reflecting the latest assessment values) and by updates to the representation of monoterpene chemistry. Updates to other reactive organic carbon systems between RACM2_ae6 and CRACMMv1.0 also affected ozone predictions and their sensitivity to emissions. Specifically, CRACMMv1.0 benzene, toluene, and xylene chemistry led to efficient NOx cycling such that CRACMMv1.0 predicted controlling aromatics reduces ozone without rural O3 disbenefits. In contrast, semivolatile to intermediate volatility alkanes introduced in CRACMMv1.0 acted to suppress O3 formation across the regional background through the sequestration of nitrogen oxides (NOx) in organic nitrates. Overall, these analyses showed that the CRACMMv1.0 mechanism within the CMAQ model was able to reasonably simulate ozone concentrations in the Northeast US during the summer of 2018 with similar magnitude and diurnal variation as the current operational Carbon Bond (CB6r3_ae7) and good model performance compared to recent modelling studies in the literature. [ABSTRACT FROM AUTHOR]

Published

2023

49. Supplementary material to &quot;Comparison of airborne measurements of NO, NO&lt;sub&gt;2&lt;/sub&gt;, HONO, NO&lt;sub&gt;y&lt;/sub&gt; and CO during FIREX-AQ&quot;

Author

Bourgeois, Ilann, primary, Peischl, Jeff, additional, Neuman, J. Andrew, additional, Brown, Steven S., additional, Allen, Hannah M., additional, Campuzano-Jost, Pedro, additional, Coggon, Matthew M., additional, DiGangi, Joshua P., additional, Diskin, Glenn S., additional, Gilman, Jessica B., additional, Gkatzelis, Georgios I., additional, Guo, Hongyu, additional, Halliday, Hannah, additional, Hanisco, Thomas F., additional, Holmes, Christopher D., additional, Huey, L. Gregory, additional, Jimenez, Jose L., additional, Lamplugh, Aaron D., additional, Lee, Young Ro, additional, Lindaas, Jakob, additional, Moore, Richard H., additional, Nowak, John B., additional, Pagonis, Demetrios, additional, Rickly, Pamela S., additional, Robinson, Michael A., additional, Rollins, Andrew W., additional, Selimovic, Vanessa, additional, St. Clair, Jason M., additional, Tanner, David, additional, Vasquez, Krystal T., additional, Veres, Patrick R., additional, Warneke, Carsten, additional, Wennberg, Paul O., additional, Washenfelder, Rebecca A., additional, Wiggins, Elizabeth B., additional, Womack, Caroline C., additional, Xu, Lu, additional, Zarzana, Kyle J., additional, and Ryerson, Thomas B., additional

Published

2022

50. Furoyl peroxynitrate (fur-PAN), a product of VOC–NOxphotochemistry from biomass burning emissions: photochemical synthesis, calibration, chemical characterization, and first atmospheric observations

Author

Roberts, James M., primary, Neuman, J. Andrew, additional, Brown, Steven S., additional, Veres, Patrick R., additional, Coggon, Matthew M., additional, Stockwell, Chelsea E., additional, Warneke, Carsten, additional, Peischl, Jeff, additional, and Robinson, Michael A., additional

Published

2022