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306. Asian outflow and trans‐Pacific transport of carbon monoxide and ozone pollution: An integrated satellite, aircraft, and model perspective

Author

Heald, Colette L., primary, Jacob, Daniel J., additional, Fiore, Arlene M., additional, Emmons, Louisa K., additional, Gille, John C., additional, Deeter, Merritt N., additional, Warner, Juying, additional, Edwards, David P., additional, Crawford, James H., additional, Hamlin, Amy J., additional, Sachse, Glen W., additional, Browell, Edward V., additional, Avery, Melody A., additional, Vay, Stephanie A., additional, Westberg, David J., additional, Blake, Donald R., additional, Singh, Hanwant B., additional, Sandholm, Scott T., additional, Talbot, Robert W., additional, and Fuelberg, Henry E., additional

Published
2003
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307. A global simulation of tropospheric ozone and related tracers: Description and evaluation of MOZART, version 2

Author

Horowitz, Larry W., primary, Walters, Stacy, additional, Mauzerall, Denise L., additional, Emmons, Louisa K., additional, Rasch, Philip J., additional, Granier, Claire, additional, Tie, Xuexi, additional, Lamarque, Jean-François, additional, Schultz, Martin G., additional, Tyndall, Geoffrey S., additional, Orlando, John J., additional, and Brasseur, Guy P., additional

Published
2003
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309. Ozone, aerosol, potential vorticity, and trace gas trends observed at high‐latitudes over North America from February to May 2000

Author

Browell, Edward V., primary, Hair, Johnathan W., additional, Butler, Carolyn F., additional, Grant, William B., additional, DeYoung, Russell J., additional, Fenn, Marta A., additional, Brackett, Vince G., additional, Clayton, Marian B., additional, Brasseur, Lorraine A., additional, Harper, David B., additional, Ridley, Brian A., additional, Klonecki, Andrzej A., additional, Hess, Peter G., additional, Emmons, Louisa K., additional, Tie, Xuexi, additional, Atlas, Elliot L., additional, Cantrell, Christopher A., additional, Wimmers, Anthony J., additional, Blake, Donald R., additional, Coffey, Michael T., additional, Hannigan, James W., additional, Dibb, Jack E., additional, Talbot, Robert W., additional, Flocke, Frank, additional, Weinheimer, Andrew J., additional, Fried, Alan, additional, Wert, Bryan, additional, Snow, Julie A., additional, and Lefer, Barry L., additional

Published
2003
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311. MOPITT cloud detection and its validation

Author

Warner, Juying, primary, Grant, David, additional, Gille, John C., additional, Drummond, James R., additional, Edwards, David P., additional, Deeter, Merritt N., additional, Francis, Gene L., additional, Ziskin, Daniel C., additional, Smith, Mark W., additional, Ho, B., additional, Emmons, Louisa K., additional, Attie, Jean-Luc, additional, and Chen, Jarmei S., additional

Published
2002
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313. MOPITT cloud detection and its validation.

Author

Warner, Juying, Grant, David, Gille, John C., Drummond, James R., Edwards, David P., Deeter, Merritt N., Francis, Gene L., Ziskin, Daniel C., Smith, Mark W., Ho, B., Emmons, Louisa K., Attie, Jean-Luc, and Chen, Jarmei S.

Published
2002
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315. A new simplified parameterization of secondary organic aerosol in the Community Earth System Model Version 2 (CESM2; CAM6.3).

Author

Jo, Duseong S., Tilmes, Simone, Emmons, Louisa K., Wang, Siyuan, and Vitt, Francis

Subjects
*CARBONACEOUS aerosols, *COMMUNITIES, *EARTH system science, *AEROSOLS, *RADIATIVE forcing, *GRID cells
Abstract

The Community Earth System Model (CESM) community has been providing versatile modeling options, with simple to complex chemistry and aerosol schemes in a single model, in order to support the broad scientific community with various research interests. While different model configurations are available in CESM and these can be used for different fields of Earth system science, simulation results that are consistent across configurations are still desirable. Here we develop a new simple secondary organic aerosol (SOA) scheme in the Community Atmosphere Model (CAM) version 6.3, the atmospheric component of the CESM. The main purpose of this simplified SOA scheme is to reduce the differences in aerosol concentrations and radiative fluxes between CAM and CAM with detailed chemistry (CAM-chem) while maintaining the computational efficiency of CAM. CAM simulation results using the default CAM6 and the new SOA schemes are compared to CAM-chem results as a reference. More consistent SOA concentrations are obtained globally when using the new SOA scheme for both temporal and spatial variabilities. The new SOA scheme shows that 62 % of grid cells globally are within a factor of 2 compared to the CAM-chem SOA concentrations, which is improved from 24 % when using the default CAM6 SOA scheme. Furthermore, other carbonaceous aerosols (black carbon and primary organic aerosol) in CAM6 become closer to CAM-chem results due to more similar microphysical aging timescales influenced by SOA coating, which in turn leads to comparable wet deposition fluxes. This results in an improved global atmospheric burden and concentrations at the high latitudes of the Northern Hemisphere compared to the full chemistry version (CAM-chem). As a consequence, the radiative flux differences between CAM-chem and CAM in the Arctic region (up to 6 W m -2) are significantly reduced for both nudged and free-running simulations. We find that the CAM6 SOA scheme can still be used for radiative forcing calculation as the high biases exist both in pre-industrial and present conditions, but studies focusing on the instantaneous radiative effects would benefit from using the SOA scheme developed in this study. The new SOA scheme also has technical advantages including the use of identical SOA precursor emissions as CAM-chem from the online biogenic emissions instead of pre-calculated emissions that may introduce differences. Future parameter updates to the CAM-chem SOA scheme can be easily translated to the new CAM SOA scheme as it is derived from the CAM-chem SOA scheme. [ABSTRACT FROM AUTHOR]

Published
2023
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320. Effects of Fire Diurnal Variation and Plume Rise on U.S. Air Quality During FIREX‐AQ and WE‐CAN Based on the Multi‐Scale Infrastructure for Chemistry and Aerosols (MUSICAv0)

Author

Tang, Wenfu, Emmons, Louisa K., Buchholz, Rebecca R., Wiedinmyer, Christine, Schwantes, Rebecca H., He, Cenlin, Kumar, Rajesh, Pfister, Gabriele G., Worden, Helen M., Hornbrook, Rebecca S., Apel, Eric C., Tilmes, Simone, Gaubert, Benjamin, Martinez‐Alonso, Sara‐Eva, Lacey, Forrest, Holmes, Christopher D., Diskin, Glenn S., Bourgeois, Ilann, Peischl, Jeff, Ryerson, Thomas B., Hair, Johnathan W., Weinheimer, Andrew J., Montzka, Denise D., Tyndall, Geoffrey S., and Campos, Teresa L.

Abstract

We analyze the effects of the diurnal cycle of fire emissions (DCFE) and plume rise on U.S. air quality using the MUSICAv0 (Multi‐Scale Infrastructure for Chemistry and Aerosols Version 0) model during the FIREX‐AQ (Fire Influence on Regional to Global Environments and Air Quality) and WE‐CAN (Western wildfire Experiment for Cloud chemistry, Aerosol absorption and Nitrogen) field campaigns. To include DCFE in the model, we employ two approaches: a DCFE climatology and DCFE derived from a satellite fire radiative power product. We also implemented two sets of plume‐rise climatologies, and two plume‐rise parameterizations. We evaluate the model performance with airborne measurements, U.S. EPA Air Quality System surface measurements, and satellite products. Overall, including plume rise improves model agreement with observations such as aircraft observations of CO and NOxfor FIREX‐AQ and WE‐CAN. Applying DCFE also improves model performance, such as for surface PM2.5in fire‐impacted regions. The impact of plume rise is larger than the impact of DCFE. Plume rise can greatly enhance modeled long‐range transport of fire‐emitted pollutants. The simulations with plume‐rise parameterizations generally perform better than the simulations with plume‐rise climatologies during FIREX‐AQ, but not for WE‐CAN. The 2019 Williams Flats Fire case study demonstrates that DCFE and plume rise change fire impacts because fire emissions are subject to different meteorology and chemistry when emitted at different times of a day and altitudes. Moreover, DCFE and plume rise also impact local‐to‐regional meteorology and chemical reaction rates. DCFE and plume rise will be included in future MUSICA versions. Fires have significant impacts on U.S. air quality. The characteristics of fires such as diurnal variation and plume rise can largely alter these impacts. We study the impact of fire diurnal variation and plume rise on U.S. air quality using a newly developed modeling system—Multi‐Scale Infrastructure for Chemistry and Aerosols Version 0 (MUSICAv0). Specifically, we employ two approaches to include the diurnal cycle of fire emissions (DCFE) and four approaches to include fire plume rise in the model. The model experiments were conducted for two campaign periods, FIREX‐AQ (Fire Influence on Regional to Global Environments and Air Quality) and WE‐CAN (Western wildfire Experiment for Cloud chemistry, Aerosol absorption and Nitrogen). We compare the model results with airborne measurements, surface measurements, and satellite products over the continental U.S. during the two campaign periods. Overall, including plume rise and/or DCFE improves model agreement with observations of the studied air‐quality‐related chemical species, and the impact of fire plume rise is larger than the impact of the DCFE. A case study also demonstrates that fire plume rise and the DCFE also impact local‐to‐regional meteorology and chemical reaction rates. Including plume rise and diurnal cycle of fire emissions (DCFE) overall improves MUSICAv0 model agreement with observationsSimulations with plume rise parameterizations generally perform better than the simulations with plume rise climatologies during FIREX‐AQPlume rise and DCFE impact local‐to‐regional meteorology and chemical reaction rates Including plume rise and diurnal cycle of fire emissions (DCFE) overall improves MUSICAv0 model agreement with observations Simulations with plume rise parameterizations generally perform better than the simulations with plume rise climatologies during FIREX‐AQ Plume rise and DCFE impact local‐to‐regional meteorology and chemical reaction rates

Published
2022
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321. Attribution of Stratospheric and Tropospheric Ozone Changes Between 1850 and 2014 in CMIP6 Models

Author

Zeng, Guang, Morgenstern, Olaf, Williams, Jonny H. T., O’Connor, Fiona M., Griffiths, Paul T., Keeble, James, Deushi, Makoto, Horowitz, Larry W., Naik, Vaishali, Emmons, Louisa K., Abraham, N. Luke, Archibald, Alexander T., Bauer, Susanne E., Hassler, Birgit, Michou, Martine, Mills, Michael J., Murray, Lee T., Oshima, Naga, Sentman, Lori T., Tilmes, Simone, Tsigaridis, Kostas, and Young, Paul J.

Abstract

We quantify the impacts of halogenated ozone‐depleting substances (ODSs), greenhouse gases (GHGs), and short‐lived ozone precursors on ozone changes between 1850 and 2014 using single‐forcing perturbation simulations from several Earth system models with interactive chemistry participating in the Coupled Model Intercomparison Project Aerosol and Chemistry Model Intercomparison Project. We present the responses of ozone to individual forcings and an attribution of changes in ozone columns and vertically resolved stratospheric and tropospheric ozone to these forcings. We find that whilst substantial ODS‐induced ozone loss dominates the stratospheric ozone changes since the 1970s, in agreement with previous studies, increases in tropospheric ozone due to increases in short‐lived ozone precursors and methane since the 1950s make increasingly important contributions to total column ozone (TCO) changes. Increases in methane also lead to substantial extra‐tropical stratospheric ozone increases. Impacts of nitrous oxide and carbon dioxide on stratospheric ozone are significant but their impacts on TCO are small overall due to several opposing factors and are also associated with large dynamical variability. The multi‐model mean (MMM) results show a clear change in the stratospheric ozone trends after 2000 due to now declining ODSs, but the trends are generally not significantly positive, except in the extra‐tropical upper stratosphere, due to relatively small changes in forcing over this period combined with large model uncertainty. Although the MMM ozone compares well with the observations, the inter‐model differences are large primarily due to the large differences in the models' representation of ODS‐induced ozone depletion. Overhead ozone absorbs harmful solar ultraviolet light, protecting life on Earth. Due to human activities since the nineteenth century, emissions of greenhouse gases (GHGs) and ozone‐depleting substances (ODSs) containing chlorine and bromine have profoundly affected stratospheric ozone. Near the Earth’ surface, ozone has increased substantially leading to worsening air quality. In this study, we use Earth system models to interactively assess the roles of ODSs, ozone‐forming pollutants, and GHGs including methane, carbon dioxide (CO2), and nitrous oxide (N2O) on ozone changes from the surface to the upper stratosphere. Whilst substantial reductions in stratospheric ozone due to ODSs occurred since the 1970s, the lower‐atmospheric ozone increases due to anthropogenic pollution have counteracted this decrease. Increases in GHGs lead to various positive and negative effects on stratospheric ozone in different regions, and their impacts vary with ODS levels in the atmosphere. Amongst the GHGs assessed here, the increase in methane leads to overwhelming positive trends in both stratospheric and tropospheric ozone through mainly chemical effects. The impact of changes in N2O and CO2on total column ozone is more uncertain due to large inter‐model differences, although their overall impact is small during the simulation period. New multi‐model results show significant positive effects of ozone precursors on near‐global ozone offsetting the negative effects of ozone‐depleting substances (ODSs)ODS and greenhouse gases dominate stratospheric ozone changes but with large inter‐model differences due to uncertainties in responses to ODS changesIncreases in carbon dioxide and nitrous oxide significantly impact stratospheric ozone, but their net effects on total columns are small due to cancellations New multi‐model results show significant positive effects of ozone precursors on near‐global ozone offsetting the negative effects of ozone‐depleting substances (ODSs) ODS and greenhouse gases dominate stratospheric ozone changes but with large inter‐model differences due to uncertainties in responses to ODS changes Increases in carbon dioxide and nitrous oxide significantly impact stratospheric ozone, but their net effects on total columns are small due to cancellations

Published
2022
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323. The Role of Snow in Controlling Halogen Chemistry and Boundary Layer Oxidation During Arctic Spring: A 1D Modeling Case Study

Author

Ahmed, Shaddy, Thomas, Jennie L., Tuite, Katie, Stutz, Jochen, Flocke, Frank, Orlando, John J., Hornbrook, Rebecca S., Apel, Eric C., Emmons, Louisa K., Helmig, Detlev, Boylan, Patrick, Huey, L. Gregory, Hall, Samuel R., Ullmann, Kirk, Cantrell, Christopher A., and Fried, Alan

Abstract

Reactive chlorine and bromine species emitted from snow and aerosols can significantly alter the oxidative capacity of the polar boundary layer. However, halogen production mechanisms from snow remain highly uncertain, making it difficult for most models to include descriptions of halogen snow emissions and to understand the impact on atmospheric chemistry. We investigate the influence of Arctic halogen emissions from snow on boundary layer oxidation processes using a one‐dimensional atmospheric chemistry and transport model (PACT‐1D). To understand the combined impact of snow emissions and boundary layer dynamics on atmospheric chemistry, we model Cl2and Br2primary emissions from snow and include heterogeneous recycling of halogens on both snow and aerosols. We focus on a 2‐day case study from the 2009 Ocean‐Atmosphere‐Sea Ice‐Snowpack campaign at Utqiaġvik, Alaska. The model reproduces both the diurnal cycle and high quantity of Cl2observed, along with the measured concentrations of Br2, BrO, and HOBr. Due to the combined effects of emissions, recycling, vertical mixing, and atmospheric chemistry, reactive chlorine is typically confined to the lowest 15 m of the atmosphere, while bromine can impact chemistry up to and above the surface inversion height. Upon including halogen emissions and recycling, the concentration of HOx(HOx= OH + HO2) at the surface increases by as much as a factor of 30 at mid‐day. The change in HOxdue to halogen chemistry, as well as chlorine atoms derived from snow emissions, significantly reduce volatile organic compound lifetimes within a shallow layer near the surface. A combination of factors including snow emissions, vertical mixing, and atmospheric chemistry explain surface Arctic halogen observationsSnow emissions of halogens impact atmospheric chemistry within a shallow layer near the surfaceSurface HOxconcentrations are increased by up to a factor of 30 due to halogen chemistry A combination of factors including snow emissions, vertical mixing, and atmospheric chemistry explain surface Arctic halogen observations Snow emissions of halogens impact atmospheric chemistry within a shallow layer near the surface Surface HOxconcentrations are increased by up to a factor of 30 due to halogen chemistry

Published
2022
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324. Reconciling Observed and Predicted Tropical Rainforest OH Concentrations

Author

Jeong, Daun, Seco, Roger, Emmons, Louisa, Schwantes, Rebecca, Liu, Yingjun, McKinney, Karena A., Martin, Scot T., Keutsch, Frank N., Gu, Dasa, Guenther, Alex B., Vega, Oscar, Tota, Julio, Souza, Rodrigo A. F., Springston, Stephen R., Watson, Thomas B., and Kim, Saewung

Abstract

We present OH observations made in Amazonas, Brazil during the Green Ocean Amazon campaign (GoAmazon2014/5) from February to March of 2014. The average diurnal variation of OH peaked with a midday (10:00–15:00) average of 1.0 × 106(±0.6 × 106) molecules cm−3. This was substantially lower than previously reported in other tropical forest photochemical environments (2–5 × 106molecules cm−3) while the simulated OH reactivity was lower. The observational data set was used to constrain a box model to examine how well current photochemical reaction mechanisms can simulate observed OH. We used one near‐explicit mechanism (MCM v3.3.1) and four condensed mechanisms (i.e., RACM2, MOZART‐T1, CB05, CB6r2) to simulate OH. A total of 14 days of analysis shows that all five chemical mechanisms were able to explain the measured OH within instrumental uncertainty of 40% during the campaign in the Amazonian rainforest environment. Future studies are required using more reliable NOxand VOC measurements to further investigate discrepancies in our understanding of the radical chemistry in the tropical rainforest. OH observations with a chemical ionization mass spectrometer during the GoAmazon2014/5 study were lower than some previous studiesBox model simulations of OH were carried out with five different chemical mechanismsObserved and model‐predicted OH concentrations agree to within measurement uncertainty of 40% OH observations with a chemical ionization mass spectrometer during the GoAmazon2014/5 study were lower than some previous studies Box model simulations of OH were carried out with five different chemical mechanisms Observed and model‐predicted OH concentrations agree to within measurement uncertainty of 40%

Published
2022
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325. Implementation and evaluation of the GEOS-Chem chemistry module version 13.1.2 within the Community Earth System Model v2.1.

Author

Fritz, Thibaud M., Eastham, Sebastian D., Emmons, Louisa K., Lin, Haipeng, Lundgren, Elizabeth W., Goldhaber, Steve, Barrett, Steven R. H., and Jacob, Daniel J.

Subjects
*COMMUNITIES, *LAND-atmosphere interactions, *ATMOSPHERIC chemistry, *ATMOSPHERIC sciences, *TROPOSPHERIC ozone, *OZONE layer
Abstract

We implement the GEOS-Chem chemistry module as a chemical mechanism in version 2 of the Community Earth System Model (CESM). Our implementation allows the state-of-the-science GEOS-Chem chemistry module to be used with identical emissions, meteorology, and climate feedbacks as the CAM-chem chemistry module within CESM. We use coupling interfaces to allow GEOS-Chem to operate almost unchanged within CESM. Aerosols are converted at each time step between the GEOS-Chem bulk representation and the size-resolved representation of CESM's Modal Aerosol Model (MAM4). Land-type information needed for dry-deposition calculations in GEOS-Chem is communicated through a coupler, allowing online land–atmosphere interactions. Wet scavenging in GEOS-Chem is replaced with the Neu and Prather scheme, and a common emissions approach is developed for both CAM-chem and GEOS-Chem in CESM. We compare how GEOS-Chem embedded in CESM (C-GC) compares to the existing CAM-chem chemistry option (C-CC) when used to simulate atmospheric chemistry in 2016, with identical meteorology and emissions. We compare the atmospheric composition and deposition tendencies between the two simulations and evaluate the residual differences between C-GC and its use as a stand-alone chemistry transport model in the GEOS-Chem High Performance configuration (S-GC). We find that stratospheric ozone agrees well between the three models, with differences of less than 10 % in the core of the ozone layer, but that ozone in the troposphere is generally lower in C-GC than in either C-CC or S-GC. This is likely due to greater tropospheric concentrations of bromine, although other factors such as water vapor may contribute to lesser or greater extents depending on the region. This difference in tropospheric ozone is not uniform, with tropospheric ozone in C-GC being 30 % lower in the Southern Hemisphere when compared with S-GC but within 10 % in the Northern Hemisphere. This suggests differences in the effects of anthropogenic emissions. Aerosol concentrations in C-GC agree with those in S-GC at low altitudes in the tropics but are over 100 % greater in the upper troposphere due to differences in the representation of convective scavenging. We also find that water vapor concentrations vary substantially between the stand-alone and CESM-implemented version of GEOS-Chem, as the simulated hydrological cycle in CESM diverges from that represented in the source NASA Modern-Era Retrospective analysis for Research and Applications (Version 2; MERRA-2) reanalysis meteorology which is used directly in the GEOS-Chem chemistry transport model (CTM). Our implementation of GEOS-Chem as a chemistry option in CESM (including full chemistry–climate feedback) is publicly available and is being considered for inclusion in the CESM main code repository. This work is a significant step in the MUlti-Scale Infrastructure for Chemistry and Aerosols (MUSICA) project, enabling two communities of atmospheric researchers (CESM and GEOS-Chem) to share expertise through a common modeling framework, thereby accelerating progress in atmospheric science. [ABSTRACT FROM AUTHOR]

Published
2022
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326. Inventory of Boreal Fire Emissions for North America in 2004: The Importance of Peat Burning and Pyro-Convective Injection

Author

Turquety, Solène, Logan, Jennifer A., Jacob, Daniel J., Hudman, Rynda C., Leung, Fok Yan, Heald, Colette L., Yantosca, Robert M., Wu, Shiliang, Emmons, Louisa K., Edwards, David P., and Sachse, Glen W.

Abstract

The summer of 2004 was one of the largest fire seasons on record for Alaska and western Canada. We construct a daily bottom-up fire emission inventory for that season, including consideration of peat burning and high-altitude (buoyant) injection, and evaluate it in a global chemical transport model (the GEOS-Chem CTM) simulation of CO through comparison with MOPITT satellite and ICARTT aircraft observations. The inventory is constructed by combining daily area burned reports and MODIS fire hot spots with estimates of fuel consumption and emission factors based on ecosystem type. We estimate the contribution from peat burning using drainage and peat distribution maps for Alaska and Canada; 17% of the reported 5.1 × 106 ha burned were located in peatlands in 2004. Our total estimate of North American fire emissions during the summer of 2004 is 30 Tg CO, including 11 Tg from peat. Including peat burning in the GEOS-Chem simulation improves agreement with MOPITT observations. The long-range transport of fire plumes observed by MOPITT suggests that the largest fires injected a significant fraction of their emissions in the upper troposphere., Earth and Planetary Sciences, Engineering and Applied Sciences

Published
2007
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327. Chemical Tomography in a Fresh Wildland Fire Plume: A Large Eddy Simulation (LES) Study

Author

Wang, Siyuan, Coggon, Matthew M., Gkatzelis, Georgios I., Warneke, Carsten, Bourgeois, Ilann, Ryerson, Thomas, Peischl, Jeff, Veres, Patrick R., Neuman, J. Andrew, Hair, Johnathan, Shingler, Taylor, Fenn, Marta, Diskin, Glenn, Huey, L. Greg, Lee, Young Ro, Apel, Eric C., Hornbrook, Rebecca S., Hills, Alan J., Hall, Samuel R., Ullmann, Kirk, Bela, Megan M., Trainer, Michael K., Kumar, Rajesh, Orlando, John J., Flocke, Frank M., and Emmons, Louisa K.

Abstract

Wildland fires involve complicated processes that are challenging to represent in chemical transport models. Recent airborne measurements reveal remarkable chemical tomography in fresh wildland fire plumes, which remain yet to be fully explored using models. Here, we present a high‐resolution large eddy simulation model coupled to chemistry to study the chemical evolution in fresh wildland fire plume. The model is configured for a large fire heavily sampled during the Fire Influence on Regional to Global Environments and Air Quality field campaign, and a variety of airborne measurements are used to evaluate the chemical heterogeneity revealed by the model. We show that the model captures the observed cross‐transect variations of a number of compounds quite well, including ozone (O3), nitrous acid (HONO), and peroxyacetyl nitrate. The combined observational and modeling results suggest that the top and edges of fresh plume drive the photochemistry, while dark chemistry is also present but in the lower part of the plume. The model spatial resolution is shown to be very important as it may shift the chemical regime, leading to biases in O3and NOxchemistry. Based on findings in this work, we speculate that the impact of small fires on air quality may be largely underestimated in models with coarse spatial resolutions. Recent fire seasons in the United States have been record‐setting for many states. Several large wildfires raged across the entire west coast and lofted smoke plumes spread to the majority of the continental U.S. From a scientific perspective, wildland fires are fascinating due to their complexity. Fires emit heat, creating a plume of hot and turbulent air. The fire plume also contains many gases and aerosol particles produced from the burning and baking of a variety of fuels on the ground (trees, grasses, leaf litter and other fallen debris, etc.). Many of these gases and aerosol particles can impact climate, air quality, and human health. For this reason, most modern air quality and climate models now consider wildland fires. However, wildland fires are fundamentally challenging for these models, because many fine‐scale and large‐scale processes are entangled at the same time. In this work, we use a high‐resolution turbulence‐resolving numerical model to study the fine details in a wildland fire plume, with implications for large‐scale air quality and climate models. Photochemistry is active at the edges of thick fire plumes, while dark chemistry is present in the lower part and below thick plumesHydroxyl radicals formed from nitrous acid drive the plume oxidation; nitrous acid may be produced on aerosolsModel resolution affects chemistry; sufficiently high spatial resolution is needed to capture the impacts of wildfires on air quality Photochemistry is active at the edges of thick fire plumes, while dark chemistry is present in the lower part and below thick plumes Hydroxyl radicals formed from nitrous acid drive the plume oxidation; nitrous acid may be produced on aerosols Model resolution affects chemistry; sufficiently high spatial resolution is needed to capture the impacts of wildfires on air quality

Published
2021
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331. Climate and air quality impacts due to mitigation of non-methane near-term climate forcers

Author

Allen, Robert J., Turnock, Steven, Nabat, Pierre, Neubauer, David, Lohmann, Ulrike, Olivié, Dirk, Oshima, Naga, Michou, Martine, Wu, Tongwen, Zhang, Jie, Takemura, Toshihiko, Schulz, Michael, Tsigaridis, Kostas, Bauer, Susanne E., Emmons, Louisa, Horowitz, Larry, Naik, Vaishali, Van Noije, Twan, Bergman, Tommi, Lamarque, Jean-François, Zanis, Prodromos, Tegen, Ina, Westervelt, Daniel M., Le Sager, Philippe, Good, Peter, Shim, Sungbo, O'Connor, Fiona, Akritidis, Dimitris, Georgoulias, Aristeidis K., Deushi, Makoto, Sentman, Lori T., John, Jasmin G., Fujimori, Shinichiro, and Collins, William J.

Subjects
13. Climate action, 7. Clean energy
Abstract

It is important to understand how future environmental policies will impact both climate change and air pollution. Although targeting near-term climate forcers (NTCFs), defined here as aerosols, tropospheric ozone, and precursor gases, should improve air quality, NTCF reductions will also impact climate. Prior assessments of the impact of NTCF mitigation on air quality and climate have been limited. This is related to the idealized nature of some prior studies, simplified treatment of aerosols and chemically reactive gases, as well as a lack of a sufficiently large number of models to quantify model diversity and robust responses. Here, we quantify the 2015–2055 climate and air quality effects of non-methane NTCFs using nine state-of-the-art chemistry–climate model simulations conducted for the Aerosol and Chemistry Model Intercomparison Project (AerChemMIP). Simulations are driven by two future scenarios featuring similar increases in greenhouse gases (GHGs) but with “weak” (SSP3-7.0) versus “strong” (SSP3-7.0-lowNTCF) levels of air quality control measures. As SSP3-7.0 lacks climate policy and has the highest levels of NTCFs, our results (e.g., surface warming) represent an upper bound. Unsurprisingly, we find significant improvements in air quality under NTCF mitigation (strong versus weak air quality controls). Surface fine particulate matter (PM2.5) and ozone (O3) decrease by −2.2±0.32 µg m−3 and −4.6±0.88 ppb, respectively (changes quoted here are for the entire 2015–2055 time period; uncertainty represents the 95 % confidence interval), over global land surfaces, with larger reductions in some regions including south and southeast Asia. Non-methane NTCF mitigation, however, leads to additional climate change due to the removal of aerosol which causes a net warming effect, including global mean surface temperature and precipitation increases of 0.25±0.12 K and 0.03±0.012 mm d−1, respectively. Similarly, increases in extreme weather indices, including the hottest and wettest days, also occur. Regionally, the largest warming and wetting occurs over Asia, including central and north Asia (0.66±0.20 K and 0.03±0.02 mm d−1), south Asia (0.47±0.16 K and 0.17±0.09 mm d−1), and east Asia (0.46±0.20 K and 0.15±0.06 mm d−1). Relatively large warming and wetting of the Arctic also occur at 0.59±0.36 K and 0.04±0.02 mm d−1, respectively. Similar surface warming occurs in model simulations with aerosol-only mitigation, implying weak cooling due to ozone reductions. Our findings suggest that future policies that aggressively target non-methane NTCF reductions will improve air quality but will lead to additional surface warming, particularly in Asia and the Arctic. Policies that address other NTCFs including methane, as well as carbon dioxide emissions, must also be adopted to meet climate mitigation goals., Atmospheric Chemistry and Physics, 20 (16), ISSN:1680-7375, ISSN:1680-7367

332. Black Carbon Deposition to the Greenland Ice Sheet from Forest Fires in Canada

Author

Thomas, Jennie L., Polashenski, Christopher M., Soja, Amber J., Louis Marelle, Casey, Kimberly A., Hyun-Deok Choi, Jean-Christophe Raut, Christine Wiedinmyer, Emmons, Louisa K., Jérome Fast, Jacques Pelon, Flanner, Mark M., Dibb, Jack E., TROPO - LATMOS, Laboratoire Atmosphères, Milieux, Observations Spatiales (LATMOS), Sorbonne Université (SU)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS)-Sorbonne Université (SU)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS), ERDC Cold Regions Research and Engineering Laboratory (CRREL), USACE Engineer Research and Development Center (ERDC), Thayer School of Engineering, Dartmouth College [Hanover], National Institute of Aerospace [Hampton] (NIA), Center for International Climate and Environmental Research [Oslo] (CICERO), University of Oslo (UiO), National Center for Atmospheric Research [Boulder] (NCAR), Atmospheric Chemistry Observations and Modeling Laboratory (ACOML), Pacific Northwest National Laboratory (PNNL), Department of Atmospheric, Oceanic, and Space Sciences [Ann Arbor] (AOSS), University of Michigan [Ann Arbor], University of Michigan System-University of Michigan System, Institute for the Study of Earth, Oceans, and Space [Durham] (EOS), University of New Hampshire (UNH), and Cardon, Catherine

Subjects
[SDE] Environmental Sciences, [SDE]Environmental Sciences
Abstract

International audience; Black carbon (BC) concentrations has been observed in 22 snowpits sampled in the northwest sector of the Greenland ice sheet in April 2014. The pits contain a strong and widespread BC aerosol deposition event, which accumulated in the pits during two snow storms between 27 July and 2 August 2013. This event comprises a significant portion (57% on average across all pits) of total BC deposition measured in the snowpits (~10 month record). We link this deposition event to forest fires burning in Canada during summer 2013 using modeling and remote sensing tools. Specifically, we use high-resolution regional chemical transport modeling (WRF- Chem) combined with high-resolution fire emissions (FINNv1.5) to study aerosol emissions, transport, and deposition to Greenland snow during this event. The model captures the timing of the BC deposition event and shows that fires in Canada were the main source of deposited BC. The potential implications for understanding the influence of BC originating from fires on the optical properties of snow is discussed.

333. Transport and chemistry of anthropogenic pollution and boreal forest fire emissions to the Arctic during summer 2008

Author

Thomas, Jennie L., Jean-Christophe Raut, Law, Kathy S., Louis Marelle, Gérard Ancellet, François Ravetta, Fast, Jerome D., Gabriele Pfister, Emmons, Louisa K., Diskin, Glenn S., Andrew Weinheimer, Anke Roiger, Hans Schlager, Cardon, Catherine, TROPO - LATMOS, Laboratoire Atmosphères, Milieux, Observations Spatiales (LATMOS), Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS), Pacific Northwest National Laboratory (PNNL), National Center for Atmospheric Research [Boulder] (NCAR), DLR Institut für Physik der Atmosphäre (IPA), and Deutsches Zentrum für Luft- und Raumfahrt [Oberpfaffenhofen-Wessling] (DLR)

Subjects
[SDE] Environmental Sciences, [SDE]Environmental Sciences
Abstract

Ozone pollution transported to the Arctic is a significant concern because of the rapid, enhanced warming in high northern latitudes, which is caused, in part, by short-lived climate forcers, such as ozone. Long-range transport of pollution contributes to background and episodic ozone levels in the Arctic. However, the extent to which plumes are photochemically active during transport, particularly during the summer, is still uncertain. Regional chemical transport model simulations are used to examine photochemical production of ozone in airmasses originating from boreal fire and anthropogenic emissions over North America and during their transport toward the Arctic during early July 2008. Model results are evaluated using POLARCAT aircraft data collected over boreal fire source regions in Canada (ARCTAS-B) and several days downwind over Greenland (POLARCAT-France and POLARCAT-GRACE) during the study period. Model results are generally in good agreement with the observations, except for certain trace gas species over boreal fire regions, in some cases indicating that the fire emissions were too low. Anthropogenic and biomass burning pollution (BB) from North America was rapidly uplifted during transport east and north to Greenland where pollution plumes were observed in the mid and upper troposphere during POLARCAT. A model sensitivity study shows that CO levels are in better agreement with POLARCAT measurements (fresh and aged fire plumes) upon doubling CO emissions from fires. Analysis of model results, using ΔO3/ΔCO enhancement ratios, shows that pollution plumes formed ozone during transport towards the Arctic. We show that aged anthropogenic and BB pollution together made an important contribution to ozone levels with a spatially averaged contribution for latitudes>55 °N of up to 6.5 ppbv (18%) from anthropogenic pollution and 3 ppbv (5.2%) from fire pollution in the model domain during the study period.

334. Sensitivity of the WRF-Chem v4.4 simulations of ozone and formaldehyde and their precursors to multiple bottom-up emission inventories over East Asia during the KORUS-AQ 2016 field campaign.

Author

Kim, Kyoung-Min, Kim, Si-Wan, Seo, Seunghwan, Blake, Donald R., Cho, Seogju, Crawford, James H., Emmons, Louisa K., Fried, Alan, Herman, Jay R., Hong, Jinkyu, Jung, Jinsang, Pfister, Gabriele G., Weinheimer, Andrew J., Woo, Jung-Hun, and Zhang, Qiang

Subjects
*EMISSION inventories, *OZONE, *VOLATILE organic compounds, *FORMALDEHYDE, *METROPOLITAN areas, *AIR quality
Abstract

In this study, the WRF-Chem v4.4 model was utilized to evaluate the sensitivity of O 3 simulations with three bottom-up emission inventories (EDGAR-HTAP v2 and v3 and KORUS v5) using surface and aircraft data in East Asia during the Korea-United States Air Quality (KORUS-AQ) campaign period in 2016. All emission inventories were found to reproduce the diurnal variations of O 3 and its main precursor NO 2 as compared to the surface monitor data. However, the spatial distributions of the daily maximum 8 h average (MDA8) O 3 in the model do not completely align with the observations. The model MDA8 O 3 had a negative (positive) bias north (south) of 30° N over China. All simulations underestimated the observed CO by 50 %–60 % over China and South Korea. In the Seoul Metropolitan Area (SMA), EDGAR-HTAP v2 and v3 and KORUS v5 simulated the vertical shapes and diurnal patterns of O 3 and other precursors effectively, but the model underestimated the observed O 3 , CO, and HCHO concentrations. Notably, the model aromatic volatile organic compounds (VOCs) were significantly underestimated with the three bottom-up emission inventories, although the KORUS v5 shows improvements. The model isoprene estimations had a positive bias relative to the observations, suggesting that the Model of Emissions of Gases and Aerosols from Nature (MEGAN) version 2.04 overestimated isoprene emissions. Additional model simulations were conducted by doubling CO and VOC emissions over China and South Korea to investigate the causes of the model O 3 biases and the effects of the long-range transport on the O 3 over South Korea. The doubled CO and VOC emission simulations improved the model O 3 simulations for the local-emission-dominant case but led to the model O 3 overestimations for the transport-dominant case, which emphasizes the need for accurate representations of the local VOC emissions over South Korea. [ABSTRACT FROM AUTHOR]

Published
2024
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335. Improving nitrogen cycling in a land surface model (CLM5) to quantify soil N2O, NO, and NH3 emissions from enhanced rock weathering with croplands.

Author

Martin, Maria Val, Blanc-Betes, Elena, Ka Ming Fung, Kantzas, Euripides P., Kantola, Ilsa B., Chiaravalloti, Isabella, Taylor, Lyla L., Emmons, Louisa K., Wieder, William R., Planavsky, Noah J., Masters, Michael D., DeLucia, Evan H., Tai, Amos P. K., and Beerling, David J.

Subjects
*NITROGEN cycle, *TROPOSPHERIC ozone, *NITROUS oxide, *WEATHERING, *FARMS, *TRACE gases, *SOIL acidity
Abstract

Surficial enhanced rock weathering (ERW) is a land-based carbon dioxide removal (CDR) strategy that involves applying crushed silicate rock (e.g., basalt) to agricultural soils. However, unintended biogeochemical interactions with the nitrogen cycle may arise through ERW increasing soil pH as basalt grains undergo dissolution that may reinforce, counteract, or even offset the climate benefits from carbon sequestration. Increases in soil pH could drive changes in the soil emissions of key non-CO 2 greenhouse gases, e.g., nitrous oxide (N 2 O), and trace gases, e.g., nitric oxide (NO) and ammonia (NH 3), that affect air quality and crop and human health. We present the development and implementation of a new improved nitrogen cycling scheme for the Community Land Model v5 (CLM5), the land component of the Community Earth System Model, allowing evaluation of ERW effects on soil gas emissions. We base the new parameterizations on datasets derived from soil pH responses of N 2 O, NO, and NH 3 in ERW field trial and mesocosm experiments with crushed basalt. These new capabilities involve the direct implementation of routines within the CLM5 N cycle framework, along with asynchronous coupling of soil pH changes estimated through an ERW model. We successfully validated simulated "control" (i.e., no ERW) seasonal cycles of soil N 2 O, NO, and NH 3 emissions against a wide range of global emission inventories. We benchmark simulated mitigation of soil N 2 O fluxes in response to ERW against a subset of data from ERW field trials in the US Corn Belt. Using the new scheme, we provide a specific example of the effect of large-scale ERW deployment with croplands on soil nitrogen fluxes across five key regions with high potential for CDR with ERW (North America, Brazil, Europe, India, and China). Across these regions, ERW implementation led to marked reductions in N 2 O and NO (both 18 %), with moderate increases in NH 3 (2 %). While further developments are still required in our implementations when additional ERW data become available, our improved N cycle scheme within CLM5 has utility for investigating the potential of ERW point-source and regional effects of soil N 2 O, NO, and NH 3 fluxes in response to current and future climates. This framework also provides the basis for assessing the implications of ERW for air quality given the role of NO in tropospheric ozone formation, as well as both NO and NH 3 in inorganic aerosol formation. [ABSTRACT FROM AUTHOR]

Published
2023
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336. Global Scale Inversions from MOPITT CO and MODIS AOD.

Author

Gaubert, Benjamin, Edwards, David P., Anderson, Jeffrey L., Arellano, Avelino F., Barré, Jérôme, Buchholz, Rebecca R., Darras, Sabine, Emmons, Louisa K., Fillmore, David, Granier, Claire, Hannigan, James W., Ortega, Ivan, Raeder, Kevin, Soulié, Antonin, Tang, Wenfu, Worden, Helen M., and Ziskin, Daniel

Subjects
*MODIS (Spectroradiometer), *WILDFIRES, *OPTICAL instruments, *CARBON monoxide, *ATMOSPHERIC models, *EMISSION inventories
Abstract

Top-down observational constraints on emissions flux estimates from satellite observations of chemical composition are subject to biases and errors stemming from transport, chemistry and prior emissions estimates. In this context, we developed an ensemble data assimilation system to optimize the initial conditions for carbon monoxide (CO) and aerosols, while also quantifying the respective emission fluxes with a distinct attribution of anthropogenic and wildfire sources. We present the separate assimilation of CO profile v9 retrievals from the Measurements of Pollution in the Troposphere (MOPITT) instrument and Aerosol Optical Depth (AOD), collection 6.1, from the Moderate Resolution Imaging Spectroradiometer (MODIS) instruments. This assimilation system is built on the Data Assimilation Research Testbed (DART) and includes a meteorological ensemble to assimilate weather observations within the online Community Atmosphere Model with Chemistry (CAM-chem). Inversions indicate an underestimation of CO emissions in CAMS-GLOB-ANT_v5.1 in China for 2015 and an overestimation of CO emissions in the Fire INventory from NCAR (FINN) version 2.2, especially in the tropics. These emissions increments are consistent between the MODIS AOD and the MOPITT CO-based inversions. Additional simulations and comparison with in situ observations from the NASA Atmospheric Tomography Mission (ATom) show that biases in hydroxyl radical (OH) chemistry dominate the CO errors. [ABSTRACT FROM AUTHOR]

Published
2023
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337. Sensitivity of the WRF-Chem v4.4 ozone, formaldehyde, and precursor simulations to multiple bottom-up emission inventories over East Asia during the KORUS-AQ 2016 field campaign.

Author

Kyoung-Min Kim, Si-Wan Kim, Seunghwan Seo, Blake, Donald R., Seogju Cho, Crawford, James H., Emmons, Louisa, Fried, Alan, Herman, Jay R., Jinkyu Hong, Jinsang Jung, Pfister, Gabriele, Weinheimer, Andrew J., Jung-Hun Woo, and Qiang Zhang

Subjects
*EMISSION inventories, *OZONE, *FORMALDEHYDE, *METROPOLITAN areas, *AIR quality, *MODEL airplanes
Abstract

In this study, the WRF-Chem v4.4 model was utilized to evaluate three bottom-up emission inventories (EDGAR-HTAP v2, v3, and KORUS v5) using surface and aircraft data in East Asia during the Korea-United States Air Quality (KORUS-AQ) campaign period in 2016. All emission inventories were found to reproduce the diurnal variations of O3 and NO2 as compared to the surface monitor data. However, the spatial distributions of the daily maximum 8-hour average (MDA8) O3 in the model do not completely align with the observations. The model MDA8 O3 had a negative (positive) bias north (south) of 30°N over China. All simulations underestimated the observed CO by 50-60% over China and South Korea. In the Seoul Metropolitan Area (SMA), EDGAR-HTAP v2, v3, and KORUS v5 simulated the vertical shapes and diurnal patterns of O3 and other precursors effectively, but the model underestimated the observed O3, CO and HCHO concentrations. Notably, the model aromatic VOCs were significantly underestimated with the three bottom-up emission inventories, although the KORUS v5 shows improvements. The model isoprene estimations had a positive bias relative to the observations, suggesting that the Model of Emissions of Gases and Aerosols from Nature (MEGAN) version 2.04 overestimated isoprene emissions. Additional model simulations were conducted by doubling CO and VOC emissions over China and South Korea to investigate the causes of the model O3 biases and the effects of the long-range transport on the O3 over South Korea. The doubled CO and VOC emission simulations improved the model O3 simulations for the local emission dominant case, but led to the model O3 overestimations for the transport dominant case, which emphasizes the need for accurate representations of the local VOC emissions over South Korea. [ABSTRACT FROM AUTHOR]

Published
2023
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338. The Fire Inventory from NCAR version 2.5: an updated global fire emissions model for climate and chemistry applications.

Author

Wiedinmyer, Christine, Kimura, Yosuke, McDonald-Buller, Elena C., Emmons, Louisa K., Buchholz, Rebecca R., Tang, Wenfu, Seto, Keenan, Joseph, Maxwell B., Barsanti, Kelley C., Carlton, Annmarie G., and Yokelson, Robert

Subjects
*TRACE gases, *MODIS (Spectroradiometer), *ATMOSPHERIC chemistry, *ATMOSPHERIC models, *CHEMICAL models, *EMISSION inventories
Abstract

We present the Fire Inventory from National Center for Atmospheric Research (NCAR) version 2.5 (FINNv2.5), a fire emissions inventory that provides publicly available emissions of trace gases and aerosols for various applications, including use in global and regional atmospheric chemistry modeling. FINNv2.5 includes numerous updates to the FINN version 1 framework to better represent burned area, vegetation burned, and chemicals emitted. Major changes include the use of active fire detections from the Visible Infrared Imaging Radiometer Suite (VIIRS) at 375 m spatial resolution, which allows smaller fires to be included in the emissions processing. The calculation of burned area has been updated such that a more rigorous approach is used to aggregate fire detections, which better accounts for larger fires and enables using multiple satellite products simultaneously for emissions estimates. Fuel characterization and emissions factors have also been updated in FINNv2.5. Daily fire emissions for many trace gases and aerosols are determined for 2002–2019 (Moderate Resolution Imaging Spectroradiometer (MODIS)-only fire detections) and 2012–2019 (MODIS + VIIRS fire detections). The non-methane organic gas emissions are allocated to the species of several commonly used chemical mechanisms. We compare FINNv2.5 emissions against other widely used fire emissions inventories. The performance of FINNv2.5 emissions as inputs to a chemical transport model is assessed with satellite observations. Uncertainties in the emissions estimates remain, particularly in Africa and South America during August–October and in southeast and equatorial Asia in March and April. Recommendations for future evaluation and use are given. [ABSTRACT FROM AUTHOR]

Published
2023
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339. Variation of atmospheric CO, d13C, and d18O at high northern latitude during 2004–2009: Observations and model simulations

Author

Park, Keyhong, Wang, Zhihui, Emmons, Louisa K., and Mak, John E.

Abstract

Atmospheric CO mixing ratios and stable isotope ratios (d13C and d18O) were measured at a high northern latitude site (Westman Islands, Iceland) from January 2004 to March 2010 in order to investigate recent multiyear trends of the sources of atmospheric carbon monoxide in the extratropical Northern Hemisphere. During this period, we observed a decrease of about 2% per year in CO mixing ratios with little significant interannual variability. The seasonal cycles for d13C and d18O in CO are similar to that in the CO mixing ratio, and there is a pronounced interannual variation in their seasonal extremes occurring in summer and fall, which is driven by changes in the relative contribution of different sources. Some of the sources of CO are anthropogenic in character (e.g., fossil fuel and biofuel combustion and agricultural waste burning), and some are primarily natural (e.g., oxidation atmospheric methane and other hydrocarbons and wildfires), and distinction among the various major sources can, more or less, be distinguished by the stable isotopic composition of CO. We compare our observations with simulations from a 3-D global chemical transport model (MOZART-4, Model for Ozone and Related Chemical Tracers, version 4). Our results indicate the observed trend of anthropogenic CO emissions is mostly responsible for the observed variation in d13C and d18O of CO during 2004–2009. Especially, the d18O enriched sources such as fossil fuel and biofuel sources are controlling the variation. The modeling results indicate decreasing trends in the fossil fuel and biofuel source contributions at Iceland of -0.61?±?0.26?ppbv/yr and -0.38?±?0.10?ppbv/yr, respectively, during the observation period. Presents a 6?year observed variation of CO and its isotope ratiosIsotope modeling results indicate anthropogenic CO controls the d18O variationDecrease of anthropogenic sources leads the decreasing trend of the CO

Published
2015
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340. On the role of lightning NOx in the formation of tropospheric ozone plumes: a global model perspective

Author

Takao, Toshinori, Emmons, Louisa, Stith, Jeff, Newchurch, Mike, Matsubara, Kouji, Hauglustaine, Didier, Ridley, Brian, Johnson, James, Brasseur, Guy, and Dye, James

Subjects
*AIR quality indexes, *NITROGEN oxides, *SIMULATION methods & models, *TROPOSPHERIC ozone
Abstract

A series of ozone transects measured each year from 1987 to 1990 over the western Pacific and eastern Indian oceans between mid-November and mid-December shows a prominent ozone maximum reaching 50-80 ppbv between 5 and 10 km in the 20 deg. S-40 deg. S latitude band. This maximum contrasts with ozone mixing ratios lower than 20 ppbv measured at the same altitudes in equatorial regions. Analyses with a global chemical transport model suggest that these elevated ozone values are part of a large-scale tropospheric ozone plume extending from Africa to the western Pacific across the Indian ocean. These plumes occur several months after the peak in biomass burning influence and during aperiod of high lightning activity in the Southern Hemisphere tropical belt. The composition and geographical extent of these plumes are similar to the ozone layers previously encountered during the biomass burning season in this region. Our model results suggest that production of nitrogen oxides from lightning strokes sustains the NOx (= NO+NO2) levels and the ozone photochemical production required in the upper troposphere to form these persistent elevated ozone layers emanating from biomass burning regions. [ABSTRACT FROM AUTHOR]

Published
2001

341. Improving nitrogen cycling in a land surface model (CLM5) to quantify soil N2O, NO and NH3 emissions from enhanced rock weathering with croplands.

Author

Martin, Maria Val, Blanc-Betes, Elena, Ka Ming Fung, Kantzas, Euripides P., Kantola, Ilsa B., Chiaravalloti, Isabella, Taylor, Lyla T., Emmons, Louisa K., Wieder, William R., Planavsky, Noah J., Masters, Michael D., DeLucia, Evan H., Tai, Amos P. K., and Beerling, David J.

Subjects
*NITROGEN cycle, *WEATHERING, *FARMS, *TRACE gases, *TROPOSPHERIC ozone, *SOIL air, *BASALT
Abstract

Surficial enhanced rock weathering (ERW) is a land-based carbon dioxide removal (CDR) strategy that involves applying crushed silicate rock (e.g., basalt) to agricultural soils. However, unintended biogeochemical interactions with the nitrogen cycle may arise through ERW increasing soil pH as basalt grains undergo dissolution that may reinforce, counteract, or even offset the climate benefits from carbon sequestration. Increases in soil pH could drive changes in the soil emissions of key non-CO2 greenhouse gases, e.g., nitrous oxide (N2O), and trace gases, e.g., nitric oxide (NO) and ammonia (NH3) that affect air quality, and crop and human health. We present the development and implementation of a new improved nitrogen cycling scheme for the land surface model Community Land Model v5 (CLM5), the land component of the Community Earth System Model, allowing evaluation of ERW effects on soil gas emissions. We base the new parameterizations on datasets derived from soil pH responses of N2O, NO and NH3 of ERW field trial and mesocosm experiments with crushed basalt. We successfully validated simulated 'control' (i.e., no ERW) seasonal cycles of soil N2O, NO and NH3 emissions against a wide range of global emission inventories. We benchmark simulated mitigation of soil N2O fluxes in response to ERW against a sub-set of data from ERW field trials in the U.S. Corn Belt. Using the new scheme, we provide a specific example of the effect of large-scale ERW deployment with croplands on soil nitrogen fluxes across five key regions with high potential for CDR with ERW (North America, Brazil, Europe, India, and China). Across these regions, ERW implementation led to marked reductions in N2O and NO (both 18%) with moderate increases in NH3 (2%). Our improved N-cycle scheme within CLM5 has utility for investigating the potential of ERW point-source and regional effects of soil N2O, NO and NH3 fluxes in response to current and future climates. This framework also provides the basis for assessing the implications of ERW for air quality given the role of NO in tropospheric ozone formation, and both NO and NH3 in inorganic aerosol formation. [ABSTRACT FROM AUTHOR]

Published
2023
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342. Importance of different parameterization changes for the updated dust cycle modeling in the Community Atmosphere Model (version 6.1).

Author

Li, Longlei, Mahowald, Natalie M., Kok, Jasper F., Liu, Xiaohong, Wu, Mingxuan, Leung, Danny M., Hamilton, Douglas S., Emmons, Louisa K., Huang, Yue, Sexton, Neil, Meng, Jun, and Wan, Jessica

Subjects
*MINERAL dusts, *ATMOSPHERIC models, *DUST, *PARAMETERIZATION, *COMMUNITIES, *AEROSOLS
Abstract

The Community Atmosphere Model (CAM6.1), the atmospheric component of the Community Earth System Model (CESM; version 2.1), simulates the life cycle (emission, transport, and deposition) of mineral dust and its interactions with physio-chemical components to quantify the impacts of dust on climate and the Earth system. The accuracy of such quantifications relies on how well dust-related processes are represented in the model. Here we update the parameterizations for the dust module, including those on the dust emission scheme, the aerosol dry deposition scheme, the size distribution of transported dust, and the treatment of dust particle shape. Multiple simulations were undertaken to evaluate the model performance against diverse observations, and to understand how each update alters the modeled dust cycle and the simulated dust direct radiative effect. The model–observation comparisons suggest that substantially improved model representations of the dust cycle are achieved primarily through the new more physically-based dust emission scheme. In comparison, the other modifications induced small changes to the modeled dust cycle and model–observation comparisons, except the size distribution of dust in the coarse mode, which can be even more influential than that of replacing the dust emission scheme. We highlight which changes introduced here are important for which regions, shedding light on further dust model developments required for more accurately estimating interactions between dust and climate. [ABSTRACT FROM AUTHOR]

Published
2022
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343. Development and Evaluation of E3SM‐MOSAIC: Spatial Distributions and Radiative Effects of Nitrate Aerosol.

Author

Wu, Mingxuan, Wang, Hailong, Easter, Richard C., Lu, Zheng, Liu, Xiaohong, Singh, Balwinder, Ma, Po‐Lun, Tang, Qi, Zaveri, Rahul A., Ke, Ziming, Zhang, Rudong, Emmons, Louisa K., Tilmes, Simone, Dibb, Jack E., Zheng, Xue, Xie, Shaocheng, and Leung, L. Ruby

Subjects
*DUST, *MINERAL dusts, *SEA salt aerosols, *AEROSOLS, *ATMOSPHERIC aerosols, *MASS transfer coefficients, *TRACERS (Chemistry)
Abstract

Nitrate aerosol plays an important role in affecting regional air quality as well as Earth's climate. However, it is not well represented or even neglected in many global climate models. In this study, we couple the Model for Simulating Aerosol Interactions and Chemistry (MOSAIC) module with the four‐mode version of the Modal Aerosol Module (MAM4) in DOE's Energy Exascale Earth System Model version 2 (E3SMv2) to simulate nitrate aerosol and its radiative effects. We find that nitrate aerosol simulated by E3SMv2‐MAM4‐MOSAIC is sensitive to the treatment of gaseous HNO3 transfer to/from interstitial particles related to accommodation coefficients of HNO3 (αHNO3 ${\alpha }_{{\mathrm{H}\mathrm{N}\mathrm{O}}_{3}}$) on dust and non‐dust particles. We compare three different treatments of HNO3 transfer: (a) a treatment (MTC_SLOW) that uses a low αHNO3 ${\alpha }_{{\mathrm{H}\mathrm{N}\mathrm{O}}_{3}}$ in the mass transfer coefficient (MTC) calculation; (b) a dust‐weighted MTC treatment (MTC_WGT) that uses a high αHNO3 ${\alpha }_{{\mathrm{H}\mathrm{N}\mathrm{O}}_{3}}$ on non‐dust particles; and (c) a dust‐weighted MTC treatment that also splits coarse mode aerosols into the coarse dust and sea salt sub‐modes in MOSAIC (MTC_SPLC). MTC_WGT and MTC_SPLC increase the global annual mean (2005–2014) nitrate burden from 0.096 (MTC_SLOW) to 0.237 and 0.185 Tg N, respectively, mostly in the coarse mode. MTC_WGT and MTC_SPLC also produce stronger nitrate direct radiative forcing (−0.048 and −0.051 W m−2, respectively) and indirect forcing (−0.33 and −0.35 W m−2, respectively) than MTC_SLOW (−0.021 and −0.24 W m−2). MTC_WGT and MTC_SPLC improve nitrate surface concentrations over remote oceans based on limited observations and vertical profiles of nitrate concentrations against aircraft measurements below 400 hPa. Plain Language Summary: Atmospheric aerosols play an important role in the Earth's climate system through their effects on radiation and clouds, and their representation continues to be a major uncertainty in global climate models (GCMs). Nitrate aerosol accounts for a notable fraction of total aerosol mass, but it is crudely represented or even neglected in many modern GCMs. In this study, we implement a comprehensive but computationally efficient aerosol chemistry module in the U.S. DOE Energy Exascale Earth System Model version 2, a state‐of‐the‐science GCM, to simulate nitrate aerosols and quantify their radiative effects. Modeled nitrate concentrations are in good agreement with aircraft observations but have positive biases relative to ground‐based network measurements. We also find that simulated nitrate lifecycle is sensitive to the treatment of gaseous HNO3 transfer to/from interstitial particles related to a parameter characterizing the sticking probability of a gas molecule at the surface of different aerosols such as dust and sea salt particles. Key Points: The Model for Simulating Aerosol Interactions and Chemistry module is implemented in Energy Exascale Earth System Model version 2 with Model for Ozone and Related chemical Tracers gas chemistry to simulate nitrate aerosolsModeled nitrate concentrations are in good agreement with aircraft observations but have positive biases at the surfaceTreatments of HNO3 accommodation coefficients and the mixing state of dust and sea salt particles significantly impact nitrate lifecycle [ABSTRACT FROM AUTHOR]

Published
2022
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344. Evaluating the Impact of Chemical Complexity and Horizontal Resolution on Tropospheric Ozone Over the Conterminous US With a Global Variable Resolution Chemistry Model.

Author

Schwantes, Rebecca H., Lacey, Forrest G., Tilmes, Simone, Emmons, Louisa K., Lauritzen, Peter H., Walters, Stacy, Callaghan, Patrick, Zarzycki, Colin M., Barth, Mary C., Jo, Duseong S., Bacmeister, Julio T., Neale, Richard B., Vitt, Francis, Kluzek, Erik, Roozitalab, Behrooz, Hall, Samuel R., Ullmann, Kirk, Warneke, Carsten, Peischl, Jeff, and Pollack, Ilana B.

Subjects
*TROPOSPHERIC ozone, *RESOLUTION (Chemistry), *TROPOSPHERIC aerosols, *CHEMICAL models, *ATMOSPHERIC boundary layer, *CHEMICAL processes, *CARBON monoxide
Abstract

A new configuration of the Community Earth System Model (CESM)/Community Atmosphere Model with full chemistry (CAM-chem) supporting the capability of horizontal mesh refinement through the use of the spectral element (SE) dynamical core is developed and called CESM/CAM-chem-SE. Horizontal mesh refinement in CESM/CAM-chem-SE is unique and novel in that pollutants such as ozone are accurately represented at human exposure relevant scales while also directly including global feedbacks. CESM/CAM-chem-SE with mesh refinement down to ~14 km over the conterminous US (CONUS) is the beginning of the Multi-Scale Infrastructure for Chemistry and Aerosols (MUSICAv0). Here, MUSICAv0 is evaluated and used to better understand how horizontal resolution and chemical complexity impact ozone and ozone precursors over CONUS as compared to measurements from five aircraft campaigns, which occurred in 2013. This field campaign analysis demonstrates the importance of using finer horizontal resolution to accurately simulate ozone precursors such as nitrogen oxides and carbon monoxide. In general, the impact of using more complex chemistry on ozone and other oxidation products is more pronounced when using finer horizontal resolution where a larger number of chemical regimes are resolved. Large model biases for ozone near the surface remain in the Southeast US as compared to the aircraft observations even with updated chemistry and finer horizontal resolution. This suggests a need for adding the capability of replacing sections of global emission inventories with regional inventories, increasing the vertical resolution in the planetary boundary layer, and reducing model biases in meteorological variables such as temperature and clouds. Plain Language Summary A new configuration of the Community Earth System Model (CESM)/Community Atmosphere Model with full chemistry (CAM-chem) supporting the capability of horizontal mesh refinement is developed. This configuration is the beginning of the Multi-Scale Infrastructure for Chemistry and Aerosols, which will create a unified infrastructure to model atmospheric chemistry and aerosols across scales in the Earth system. The capability in CESM/CAM-chem to use grids with horizontal mesh refinement is a novel advancement because the regional and global model components are seamlessly connected such that there is consistency in the physical and chemical processes between the components, which increases accuracy in prediction and efficiency in model development. This work evaluates this new model configuration over the conterminous US against measurements from five aircraft campaigns, which occurred during 2013. By evaluating model results against observations not only for ozone, but also ozone precursors, photolysis rate constants, temperature, planetary boundary layer height, etc., model skill at representing processes important for ozone formation and loss is inferred. Updates to horizontal resolution and chemistry improve simulated ozone and ozone precursors as compared to observations, but biases remain. The physical and chemical processes that are missing or erroneous in the model are highlighted to help prioritize future work. [ABSTRACT FROM AUTHOR]

Published
2022
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345. Large contribution of biomass burning emissions to ozone throughout the global remote troposphere.

Author

Bourgeois, Ilann, Peischl, Jeff, Neuman, J. Andrew, Brown, Steven S., Thompson, Chelsea R., Aikin, Kenneth C., Allen, Hannah M., Angot, Héléne, Apel, Eric C., Baublitz, Colleen B., Brewer, Jared F., Campuzano-Jost, Pedro, Commaneg, Róisín, Crounse, John D., Daube, Bruce C., DiGangi, Joshua P., Diskin, Glenn S., Emmons, Louisa K., Fiore, Arlene M., and Gkatzelis, Georgios I.

Subjects
*BIOMASS burning, *OZONE, *TROPOSPHERIC ozone, *TROPOSPHERE, *RADIATIVE forcing
Abstract

Ozone is the third most important anthropogenic greenhouse gas after carbon dioxide and methane but has a larger uncertainty in its radiative forcing, in part because of uncertainty in the source characteristics of ozone precursors, nitrogen oxides, and volatile organic carbon that directly affect ozone formation chemistry. Tropospheric ozone also negatively affects human and ecosystem health. Biomass burning (BB) and urban emissions are significant but uncertain sources of ozone precursors. Here, we report globalscale, in situ airborne measurements of ozone and precursor source tracers from the NASA Atmospheric Tomography mission. Measurements from the remote troposphere showed that tropospheric ozone is regularly enhanced above background in polluted air masses in all regions of the globe. Ozone enhancements in air with high BB and urban emission tracers (2.1 to 23.8 ppbv [parts per billion by volume]) were generally similar to those in BB-influenced air (2.2 to 21.0 ppbv) but larger than those in urbaninfluenced air (27.7 to 6.9 ppbv). Ozone attributed to BB was 2 to 10 times higher than that from urban sources in the Southern Hemisphere and the tropical Atlantic and roughly equal to that from urban sources in the Northern Hemisphere and the tropical Pacific. Three independent global chemical transport models systematically underpredict the observed influence of BB on tropospheric ozone. Potential reasons include uncertainties in modeled BB injection heights and emission inventories, export efficiency of BB emissions to the free troposphere, and chemical mechanisms of ozone production in smoke. Accurately accounting for intermittent but large and widespread BB emissions is required to understand the global tropospheric ozone burden. [ABSTRACT FROM AUTHOR]

Published
2021
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346. Harmonized Emissions Component (HEMCO) 3.0 as a versatile emissions component for atmospheric models: application in the GEOS-Chem, NASA GEOS, WRF-GC, CESM2, NOAA GEFS-Aerosol, and NOAA UFS models.

Author

Lin, Haipeng, Jacob, Daniel J., Lundgren, Elizabeth W., Sulprizio, Melissa P., Keller, Christoph A., Fritz, Thibaud M., Eastham, Sebastian D., Emmons, Louisa K., Campbell, Patrick C., Baker, Barry, Saylor, Rick D., and Montuoro, Raffaele

Subjects
*ATMOSPHERIC models, *ATMOSPHERIC chemistry, *EMISSION inventories, *WEATHER forecasting, *CHEMICAL models
Abstract

Emissions are a central component of atmospheric chemistry models. The Harmonized Emissions Component (HEMCO) is a software component for computing emissions from a user-selected ensemble of emission inventories and algorithms. It allows users to re-grid, combine, overwrite, subset, and scale emissions from different inventories through a configuration file and with no change to the model source code. The configuration file also maps emissions to model species with appropriate units. HEMCO can operate in offline stand-alone mode, but more importantly it provides an online facility for models to compute emissions at runtime. HEMCO complies with the Earth System Modeling Framework (ESMF) for portability across models. We present a new version here, HEMCO 3.0, that features an improved three-layer architecture to facilitate implementation into any atmospheric model and improved capability for calculating emissions at any model resolution including multiscale and unstructured grids. The three-layer architecture of HEMCO 3.0 includes (1) the Data Input Layer that reads the configuration file and accesses the HEMCO library of emission inventories and other environmental data, (2) the HEMCO Core that computes emissions on the user-selected HEMCO grid, and (3) the Model Interface Layer that re-grids (if needed) and serves the data to the atmospheric model and also serves model data to the HEMCO Core for computing emissions dependent on model state (such as from dust or vegetation). The HEMCO Core is common to the implementation in all models, while the Data Input Layer and the Model Interface Layer are adaptable to the model environment. Default versions of the Data Input Layer and Model Interface Layer enable straightforward implementation of HEMCO in any simple model architecture, and options are available to disable features such as re-gridding that may be done by independent couplers in more complex architectures. The HEMCO library of emission inventories and algorithms is continuously enriched through user contributions so that new inventories can be immediately shared across models. HEMCO can also serve as a general data broker for models to process input data not only for emissions but for any gridded environmental datasets. We describe existing implementations of HEMCO 3.0 in (1) the GEOS-Chem "Classic" chemical transport model with shared-memory infrastructure, (2) the high-performance GEOS-Chem (GCHP) model with distributed-memory architecture, (3) the NASA GEOS Earth System Model (GEOS ESM), (4) the Weather Research and Forecasting model with GEOS-Chem (WRF-GC), (5) the Community Earth System Model Version 2 (CESM2), and (6) the NOAA Global Ensemble Forecast System – Aerosols (GEFS-Aerosols), as well as the planned implementation in the NOAA Unified Forecast System (UFS). Implementation of HEMCO in CESM2 contributes to the Multi-Scale Infrastructure for Chemistry and Aerosols (MUSICA) by providing a common emissions infrastructure to support different simulations of atmospheric chemistry across scales. [ABSTRACT FROM AUTHOR]

Published
2021
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347. The Multi-Scale Infrastructure for Chemistry and Aerosols (MUSICA).

Author

Pfister, Gabriele G., Eastham, Sebastian D., Arellano, Avelino F., Aumont, Bernard, Barsanti, Kelley C., Barth, Mary C., Conley, Andrew, Davis, Nicholas A., Emmons, Louisa K., Fast, Jerome D., Fiore, Arlene M., Gaubert, Benjamin, Goldhaber, Steve, Granier, Claire, Grell, Georg A., Guevara, Marc, Henze, Daven K., Hodzic, Alma, Xiaohong Liu, and Marsh, Daniel R.

Subjects
*ATMOSPHERIC aerosols, *AEROSOLS, *ATMOSPHERIC chemistry, *ATMOSPHERIC composition, *AIR quality
Abstract

To explore the various couplings across space and time and between ecosystems in a consistent manner, atmospheric modeling is moving away from the fractured limited-scale modeling strategy of the past toward a unification of the range of scales inherent in the Earth system. This paper describes the forward-looking Multi-Scale Infrastructure for Chemistry and Aerosols (MUSICA), which is intended to become the next-generation community infrastructure for research involving atmospheric chemistry and aerosols. MUSICA will be developed collaboratively by the National Center for Atmospheric Research (NCAR) and university and government researchers, with the goal of serving the international research and applications communities. The capability of unifying various spatiotemporal scales, coupling to other Earth system components, and process-level modularization will allow advances in both fundamental and applied research in atmospheric composition, air quality, and climate and is also envisioned to become a platform that addresses the needs of policy makers and stakeholders. [ABSTRACT FROM AUTHOR]

Published
2020
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348. Air pollution trends measured from Terra: CO and AOD over industrial, fire-prone, and background regions.

Author

Buchholz, Rebecca R., Worden, Helen M., Park, Mijeong, Francis, Gene, Deeter, Merritt N., Edwards, David P., Emmons, Louisa K., Gaubert, Benjamin, Gille, John, Martínez-Alonso, Sara, Tang, Wenfu, Kumar, Rajesh, Drummond, James R., Clerbaux, Cathy, George, Maya, Coheur, Pierre-François, Hurtmans, Daniel, Bowman, Kevin W., Luo, Ming, and Payne, Vivienne H.

Subjects
*AIR quality management, *CARBONACEOUS aerosols, *BIOMASS burning, *COMBUSTION efficiency, *CARBON monoxide, *AIR quality, *AIR pollution, *WATER storage
Abstract

Following past studies to quantify decadal trends in global carbon monoxide (CO) using satellite observations, we update estimates and find a CO trend in column amounts of about −0.50 % per year between 2002 to 2018, which is a deceleration compared to analyses performed on shorter records that found −1 % per year. Aerosols are co-emitted with CO from both fires and anthropogenic sources but with a shorter lifetime than CO. A combined trend analysis of CO and aerosol optical depth (AOD) measurements from space helps to diagnose the drivers of regional differences in the CO trend. We use the long-term records of CO from the Measurements of Pollution in the Troposphere (MOPITT) and AOD from the Moderate Resolution Imaging Spectroradiometer (MODIS) instrument. Other satellite instruments measuring CO in the thermal infrared, AIRS, TES, IASI, and CrIS, show consistent hemispheric CO variability and corroborate results from the trend analysis performed with MOPITT CO. Trends are examined by hemisphere and in regions for 2002 to 2018, with uncertainties quantified. The CO and AOD records are split into two sub-periods (2002 to 2010 and 2010 to 2018) in order to assess trend changes over the 16 years. We focus on four major population centers: Northeast China, North India, Europe, and Eastern USA, as well as fire-prone regions in both hemispheres. In general, CO declines faster in the first half of the record compared to the second half, while AOD trends show more variability across regions. We find evidence of the atmospheric impact of air quality management policies. The large decline in CO found over Northeast China is initially associated with an improvement in combustion efficiency, with subsequent additional air quality improvements from 2010 onwards. Industrial regions with minimal emission control measures such as North India become more globally relevant as the global CO trend weakens. We also examine the CO trends in monthly percentile values to understand seasonal implications and find that local changes in biomass burning are sufficiently strong to counteract the global downward trend in atmospheric CO, particularly in late summer. • The global decreasing trend in CO has shown a recent slowdown. • Fire emissions in NH boreal regions counteract decreasing CO in late summer. • AOD helps interpret CO trends and variability. • Trends in four industrial regions show impact from varying air quality controls. [ABSTRACT FROM AUTHOR]

Published
2021
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349. The Korea-United States Air Quality (KORUS-AQ) field study.

Author

Crawford JH, Ahn JY, Al-Saadi J, Chang L, Emmons LK, Kim J, Lee G, Park JH, Park RJ, Woo JH, Song CK, Hong JH, Hong YD, Lefer BL, Lee M, Lee T, Kim S, Min KE, Yum SS, Shin HJ, Kim YW, Choi JS, Park JS, Szykman JJ, Long RW, Jordan CE, Simpson IJ, Fried A, Dibb JE, Cho S, and Kim YP

Abstract

The Korea-United States Air Quality (KORUS-AQ) field study was conducted during May-June 2016. The effort was jointly sponsored by the National Institute of Environmental Research of South Korea and the National Aeronautics and Space Administration of the United States. KORUS-AQ offered an unprecedented, multi-perspective view of air quality conditions in South Korea by employing observations from three aircraft, an extensive ground-based network, and three ships along with an array of air quality forecast models. Information gathered during the study is contributing to an improved understanding of the factors controlling air quality in South Korea. The study also provided a valuable test bed for future air quality-observing strategies involving geostationary satellite instruments being launched by both countries to examine air quality throughout the day over Asia and North America. This article presents details on the KORUS-AQ observational assets, study execution, data products, and air quality conditions observed during the study. High-level findings from companion papers in this special issue are also summarized and discussed in relation to the factors controlling fine particle and ozone pollution, current emissions and source apportionment, and expectations for the role of satellite observations in the future. Resulting policy recommendations and advice regarding plans going forward are summarized. These results provide an important update to early feedback previously provided in a Rapid Science Synthesis Report produced for South Korean policy makers in 2017 and form the basis for the Final Science Synthesis Report delivered in 2020.

Published
2021
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