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The 11th International GEOS-Chem Meeting (IGC11) June 11-14, 2024
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<p align="justify">
	<strong>
	Monday, June 10: <a href="#clinics">Model Clinics</a>
	<br class="clearfix" />
	Tuesday, June 11: <a href="#overview">Model Overview</a> | <a href="#chem-climate">Chemistry-Climate</a> | <a href="#airquality">Air Quality</a> | <a href="#tue_wg">Breakouts</a> | <a href="#tue_posters">Posters</a>
	<br class="clearfix" />
	Wednesday, June 12: <a href="#chemistryI">Chemistry I</a> | <a href="#model_dev">Model Developments</a> | <a href="#aerosols">Aerosols</a> | <a href="#wed_wg">Breakouts</a> | <a href="#wed_posters">Posters</a>
	<br class="clearfix" />
	Thursday, June 13: <a href="#chemistryII">Chemistry II</a> | <a href="#fires">Fires</a> | <a href="#carbon">Carbon Gases</a>| <a href="#thu_wg">reakouts</a> | <a href="#thu_posters">Posters</a>
	<br class="clearfix" />
	Friday, June 14: <a href="#wg">Working Groups</a> | <a href="#future">Looking Ahead</a></strong>
</p>

<div>
	<h2>
		Monday, June 10
	</h2>
	<a name="clinics" id="clinics"></a><strong>Model Clinics</strong>

	<ul>
	    <li>
			<a href="https://drive.google.com/file/d/1R9jaYR-fF3lfk2G436uskGzuhr-9Dd95/view?usp=drive_link">Getting Started with GEOS-Chem</a> (Bob Yantosca, Harvard; Melissa Sulprizio, Harvard)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1QZnQgk6SVHCK7bplgYyuNXVoP_s-0bwj/view?usp=drive_link">Working with the high-performance GEOS-Chem (GCHP)</a> (Sebastian Eastham, Imperial College London)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1K5pk4Y-S37_b105MEd0533f4Et3cQJJy/view?usp=drive_link">Running GEOS-Chem with WRF (WRF-GC)</a> (Xu Feng, Harvard; Haipeng Lin, Harvard)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1cgu1cGDpM2LrnNYC7Y3Bl1_-L-NS0oi1/view?usp=drive_link">Working with the GEOS-Chem adjoint</a> (Daven Henze, CU Boulder)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1VHWL32K43kKqmOre0xSWv6QinbF0SSkL/view?usp=drive_link">Running GC within CESM</a> (Haipeng Lin, Harvard)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/16kSMlB3uOCMGgQqwfExbDtprMReNgcVO/view?usp=drive_link">Running GISS-GC/GCAP/ICECAP</a> (Lee Murray, U. Rochester)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1m5WFqxT-1sVFNqlJfudRLIYBUyHz3IN0/view?usp=drive_link">Using CHEEREIO LETKF</a> (Drew Pendergrass, Harvard)
		</li>
	</ul>
</div>

<div>
	<h2>
		Tuesday, June 11
	</h2>
	<a name="overview" id="overview"></a><strong>Model overview (Chair: Eloise Marais, U. College London)</strong>

	<ul>
	    <li>
			Welcome to IGC11 (Eloise Marais, U. College London)
		</li>
		<li>
			Welcome to Washington University (Dean Aaron Bobick, WashU)
		</li>
		<li>
		    Welcome from Center for the Environment (Dan Giammar, WashU)
		</li>
		<li>
			Welcome from McDonnell Academy (Laura Benoist, WashU)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1TCWoltnHCiTPmAnlT8b-N2Ajon0FgEyn/view?usp=drive_link">GEOS-Chem overview</a> (Randall Martin, WashU)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1bP6rr3i474phzMR0fb4ZJgE2IV5bVgib/view?usp=drive_link">GEOS-Chem adjoint overview</a> (Daven Henze, Colorado U. Boulder)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1MkLroHB9S-8RZx9CZ7ubPV0JkDrjpnWC/view?usp=drive_link">WRF-GC v3.0: developments and applications</a> (Tzung-May Fu, SUSTech)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1eZi0CW6JfRo-OKBN1FyXbbuiRgn_SoRH/view?usp=drive_link">GEOS system updates</a> (Steven Pawson, NASA GMAO)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1rwlAlYfeCxz95DNfJ3SCXWmEAn9LRuVJ/view?usp=drive_link">GEOS-Chem in GEOS: New developments and comparison with the offline model</a> (Viral Shah, NASA GSFC)
		</li>
	</ul>
	
	<a name="chem-climate" id="chem-climate"></a>
	<strong>Chemistry-climate-ecosystems-health (Chair: Lyatt Jaeglé, U. Washington)</strong>
	<ul>
	    <li>
			GEOS-Chem as a testbed for assessing aerosol radiative effects (Bethany Sutherland, North Carolina State U.)
	    <li>
	        <a href="https://drive.google.com/file/d/1JxydQLfzNln9wvdbfeUvQ04X0iZfiEmp/view?usp=drive_link">Using GEOS-Chem to estimate future climate penalties and benefits to human mortality and crop losses</a> (Lee Murray, U Rochester)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1xoczYkfabSsYh-49eaErGrSvCpMY5ihQ/view?usp=drive_link">Air pollution-vegetation interactions in GEOS-Chem</a> (Hong Liao, NUIST)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1D4vb1NCobDPXhFrCWSE1mGFEpB6D2nCr/view?usp=drive_link">Global health burden of ammonia emissions from fossil-fuel derived synthetic nitrogen fertiliser</a> (Karn Vohra, U. College London)
		</li>
		<li>
			Exploring atmospheric phosphorus sources, transport, and trends: Development of an atmospheric phosphorus description in GEOS-Chem (Olivia Norman, MIT)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1uUKpptIO_BmZYcExphi82UJaUUONuf4U/view?usp=drive_link">The growing impact of satellite megaconstellation launch and re-entry emissions on radiative forcing and stratospheric ozone depletion</a> (Connor Barker, U. College London)
		</li>
	</ul>
	
	<a name="airquality" id="airquality"></a>
	<strong>Air Quality (Chair: Seb Eastham, Imperial College London)</strong>
	<ul>
	    <li>
			KEYNOTE: Evolving urban air quality (Brian McDonald, NOAA)
		</li>
		<li>
			The impacts of reactive nitrogen emissions on global PM2.5 air pollution (Lin Zhang, Peking U.)
		</li>
		<li>
			Complex ozone-temperature relationship over the North China Plain (Ke Li, NUIST)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1i8gHY10DpVDaDlrHd75QMATWuNNjQX7y/view?usp=drive_link">Improving top-down NOx emission estimates with synthetic columns from GEOS-Chem: Application in African hotspots</a> (Eloise Marais, U. College London)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1yjShrSwakLemAjoI77i3NVLyQuaTUoRT/view?usp=drive_link">Factors affecting urban HONO interpreted with a MAX-DOAS instrument and GEOS-Chem</a> (Eleanor Gershenson-Smith, U. College London)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1if0fde5zfNq7bNBM9mY8d2q4GoYJvpRR/view?usp=drive_link">Aggravated surface O3 pollution primarily driven by meteorological variation in China during the COVID-19 pandemic lockdown period</a> (Zhendong Lu, U. Iowa)
		</li>
		<li>
			Sensitivity of air quality in Eastern Canada to transboundary pollution and meteorology: Understanding potential climate-AQ feedbacks (Robin Stevens, U. Montréal)
		</li>
	</ul>

	<a name="tuewg" id="tue_wg"></a>
	<strong>Working Group Breakouts</strong>
	<ul>
	    <li>
            Emissions Working Group (chairs: Eloise Marais, U. College London; Lyatt Jaeglé, U. Washington; Jintai Lin, Peking U.)
		</li>
		<li>
			Chemistry-Climate Working Group (chairs: Lee Murray, U. Rochester; Hong Liao, NUIST)
		</li>
		<li>
			Transport Working Group (chairs: Katie Travis, NASA LaRC; Andrew Schuh, CSU)
		</li>
		<li>
			Stratosphere Working Group (chairs: Seb Eastham, MIT; Dylan Jones, U. Toronto; Pam Wales, NASA GSFC)
		</li>
	</ul>
	
	<a name="tue_posters" id="tue_posters"></a>
	<strong>Posters</strong>
	<ul>
	    <li>Constraining the California ammonia budget (Will Porter, UC Riverside)</li>
	    <li>Modeling the effect of drought stress on biogenic isoprene emissions in South Korea (Yongcheol Jeong, U. Houston)</li>
	    <li>Isoprene emissions impact atmospheric oxidative capacity and methane lifetimes (James Yoon, U. Washington)</li>
	    <li>Estimating the contribution of anthropogenic NOx emissions to the 2019 global annual pediatric asthma health burden attributable to NO2 with the GEOS Chem adjoint (Patrick Wiecko, CU Boulder)</li>
	    <li>GEOS-Chem-APM for (1) physics-guided machine learning parameterizations and (2) aerosol pollution exposure and health disparities (Arshad Nair, SUNY Albany)</li>
	    <li>Linking water usage to future air quality: Adding a source of halogens from playa dust to GEOS-Chem (Joey Bail, U. Utah)</li>
	    <li>Near-real-time satellite AOD measurements and chemical transport modeling (Tessa Clarizio, UIUC)</li>
	    <li>Investigating rocket launch emissions impact variation with changing launch latitude (Helena McDonald, MIT)</li>
	    <li>Modeling and remote Sensing of NO2 and HCHO diurnal variability: Results from Boston and Salt Lake City (Jeff Geddes, Boston U.)</li>
	    <li>A bias-corrected GEMS NO2 satellite product and its applications (Yujin Oak, Harvard)</li>
	    <li>Constraining model sulfate production mechanisms with observations in South Korea (Katie Travis, NASA LaRC)</li>
	    <li>Emission inventories underestimate black carbon in the Global South as revealed by comparison of GCHP simulations with measurements (Yuxuan Ren, WashU)</li>
	    <li>Background ozone in China (Danyuting Zhang, NUIST and Harvard)</li>
	    <li>Ozone production, VOC sources, and model-measurement comparisons from the AEROMMA field campaign (Kelvin Bates, NOAA CSL and CU Boulder)</li>
	    <li>Enhancing regional estimation of fine particulate matter species concentrations by including GEOS-Chem a priori information into deep learning (Siyuan Shen, WashU)</li>
	    <li>Impacts of anthropogenic emissions and meteorology on spring ozone differences in San Antonio, Texas between 2017 and 2021 (Tabitha Lee, U. Houston)
	    <li>Interpretating driving factors of global diel fine particulate matter variation using GEOS- Chem and in situ observations (Yanshun Li, WashU)</li>
	    <li>Evaluating WRF-GC v2.0 predictions of boundary layer height and vertical ozone profile during the 2021 TRACER-AQ campaign in Houston, Texas (Shailaja Wasti, U, Houston)</li>
	    <li>Constraining summertime anthropogenic VOC emissions in Salt Lake City, Utah (Emily Cope, U. Montana)</li>
	    <li>Adding a source of halogens from road-salt applications to GEOS-Chem (Shuying Zhao, U. Utah)</li>
	    <li>Wildfire emissions and impact in Missoula, Montana during 2021 wildfire season (Lu Tan, U. Montana)</li>
	</ul>
</div>

<div>
	<h2>
		Wednesday, June 12
	</h2>

	<a name="chemistryI" id="chemistryI"></a>
	<strong>Chemistry I (Chair: Lu Hu, U. Montana)</strong>
	<ul>
	    <li>
			<a href="https://drive.google.com/file/d/14axS-PYXbvEMIvEW7MLLt4M46AjzjgRW/view?usp=drive_link">Drivers of increasingly high tropospheric ozone in East Asia</a> (Nadia Colombi, Harvard)
		</li>
		<li>
			The shrinking climate niche for tropospheric ozone and mercury depletion events (Chris Holmes, FSU)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1wRn4bsy0dMciu0dDpgXMZK5ndQM97lmd/view?usp=drive_link">Interpreting GEMS geostationary satellite observations of the diurnal variation of nitrogen dioxide (NO2) over East Asia</a> (Laura Yang, Harvard)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1WzEGZgVx_20d1zBXWUcEqndl9Nv5zVbc/view?usp=drive_link">Using GEOS-Chem to interpret summertime hourly variation of NO2 columns with implications for geostationary satellite applications</a> (Deepangsu Chatterjee, WashU)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/17VOkG1bwpe6FVsEuc-1q1R9hltFmq_HB/view?usp=drive_link">Development, evaluation and interpretation of a simultaneous simulation of CH4, 13CH4 and CH3D within GEOS-Chem during the Recent Hiatus Period</a> (Mingjian Shi, U. Rochester)
		</li>
	</ul>
	
	<a name="model_dev" id="model_dev"></a>
	<strong>Model developments (Chair: Hannah Horowitz, UIUC)</strong>
	<ul>
	    <li>
			<a href="https://drive.google.com/file/d/1P5rki2Az0biEkb3svFJRivo_S3uyPqCa/view?usp=drive_link">Intercomparison of GEOS-Chem and CAM-chem tropospheric oxidant chemistry within the Community Earth System Model version 2 (CESM2)</a> (Haipeng Lin, Harvard)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1nGxKdrQkR6Rh4viVHYxMugw5mJjtYtbK/view?usp=drive_link">Using GCHP with containers and clouds</a> (Yidan Tang, WashU)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1Xiy4oZDvzpkwHTZUBCgcv02luoXA7f7w/view?usp=drive_link">Integrated Methane Inversion (IMI 2.0)</a> (Melissa Sulprizio, Harvard)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1mZEUyJCJ5FqpkCkwyR5vAmFvd7AOjyXp/view?usp=drive_link">New GEOS-Chem developments to examine biosphere-agriculture-atmosphere interactions and implications for air quality</a> (Amos Tai, Chinese U. Hong Kong)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1Cwas8vzif40cuOHecrXIoLSkHlsKCXr6/view?usp=drive_link">Impact of GCHP spatial resolution on global geophysical satellite-derived fine particulate matter</a> (Dandan Zhang, WashU)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1yQxpxid0yN3YUl75x-zH69ucG0mIWQ1G/view?usp=drive_link">Chemistry in the twilight zone: creation of a mechanism analysis interface for GEOS- Chem to address a computational bottleneck in air quality forecasts</a> (Obin Sturm, USC)
		</li>
	</ul>
	
	<a name="aerosols" id="aerosols"></a>
	<strong>Aerosols (Chair: Colette Heald, ETH)</strong>
	<ul>
	    <li>
			KEYNOTE: Evolution of reactive organic carbon and its toxicity in wildfire plumes (Havala Pye, EPA)
		</li>
		<li>
			Impact of horizontal resolution on aerosol number and size in GCHP-TOMAS (Betty Croft, WashU and Dalhousie)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/14m32oXndzdQfpGbk3tGzwxbDdotCSUG8/view?usp=drive_link">Impact of air refreshing and cloud ice uptake limitations on vertical profiles and wet depositions of nitrate, ammonium, and sulfate</a> (Gan Luo, SUNY Albany)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1P6bdeZf2IOWkKbiSIl4IoPI1LaHXUzOc/view?usp=drive_link">Diagnosing the sensitivity of particulate nitrate to precursor emissions using satellite observations of NH3 and NO2</a> (Ruijun Dang, Harvard)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1aWtYNdcfMRANB3wxUTL0RMnEZv86vCSd/view?usp=drive_link">Global spatial variation in the PM2.5 to AOD relationship and Its driving factors</a> (Haihui Zhu, WashU)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1oy-_VA5PEiPcH-6dHOg2Vjbtcv3o38gd/view?usp=drive_link">Capturing the relative-humidity-sensitive gas–particle partitioning of organic aerosols in GEOS-Chem</a> (Camilo Serrano Damha, McGill)
		</li>
	</ul>
	
    <a name="wed_wg" id="wed_wg"></a>
    <strong>Working Group Breakouts</strong>
	<ul>
	    <li>
			Aerosols Working Group (chairs: Becky Alexander, U. Washington; Jeff Pierce, CSU; Will Porter, UC Riverside; Fangqun Yu, SUNY-Albany)
		</li>
		<li>
			Carbon gases Working Group (chairs: Kevin Bowman, JPL; Dylan Jones, U. Toronto)
		</li>
		<li>
			Surface-atmosphere exchange Working Group (chairs: Jeff Geddes, Boston U.; Chris Holmes, Florida State U.; Amos Tai, Chinese U. Hong Kong)
		</li>
		<li>
			Hg and POPs Working Group (chairs: Jenny Fisher, U Wollongong; Hannah Horowitz, UIUC; Yanxu Zhang, Nanjing U.)
		</li>
	</ul>
	
    <a name="wed_posters" id="wed_posters"></a>
    <strong>Posters</strong>
	<ul>
	    <li>2022 GEOS-Chem v14 ozone evaluation using sondes, satellites and surface measurements (Barron Henderson, EPA)</li>
	    <li>A new source of HO2? (Paolo Sebastianelli, U. Wollongong)</li>
	    <li>Variable sensitivity of GCHP simulated ozone to grid resolution: combined effects from meteorology and chemistry (Chi Li, WashU)</li>
	    <li>Improved representation of lightning NOx in GEOS-Chem informed by vertical profiles of NO2 and O3 from cloud-slicing TROPOMI (Bex Horner, U. College London)</li>
	    <li>Current chemical mechanisms fail to reproduce trends in DMS oxidation products observed in Arctic ice cores (Ursula Jongebloed, U. Washington)</li>
	    <li>Development and evaluation of dimethyl sulfide oxidation mechanism in the marine atmosphere (Linia Tashmim, UC Riverside)</li>
	    <li>Characterizing the global tropospheric budget of NOy (Ishir Dutta, MIT)</li>
	    <li>Global model of atmospheric chlorate (Yuk Chun Chan, U. Washington)</li>
	    <li>Space-based observations of tropospheric ethane map emissions from fossil fuel extraction (Jared Brewer, U Minnesota)</li>
	    <li>Automated GEOS-Chem mechanism emulator for F0AM box model (Jessica Haskins, U. Utah)</li>
	    <li>GCHP-EnKF multi-constituent satellite data assimilation (Kazuyuki Miyazaki, JPL)</li>
	    <li>GEOS-Chem-hyd: Enabling calculation of numerically exact, second-order sensitivities (Samuel Akinjole, Drexel)</li>
	    <li>Lagrangian versus Eulerian perspectives of new particle formation events (Sam O’Donnell. Colorado State U.)</li>
	    <li>Calculation of sub-micron and super-micron particle fluxes by coupling CALIPSO and GEOS-Chem (Ajmal Rasheeda, North Carolina State U.)</li>
	    <li>Integrated model-measurement approaches to laboratory SOA studies (Hannah Kenagy, MIT)</li>
	    <li>Reconciling differences of GEOS-Chem simulations and globally-distributed ground- based measurements of mineral dust (Yu Yan, WashU)</li>
	    <li>Global simulations of secondary organic aerosol phase state and equilibration timescales with GEOS-Chem (Regina Luu, UC Irvine)</li>
	    <li>Framework for modeling dark-brown carbon optical properties (Taveen Singh Kapoor, WashU)</li>
	    <li>Using accumulated precipitation and air mass history along transport trajectories to interpret aerosol observations over the western North Atlantic Ocean (Bo Zhang, National Institute of Aerospace)</li>
	    <li>Global modeling of organic aerosols based on a new emission inventory and an updated mechanism in GEOS-Chem (Ruochong Xu, Tsinghua U.)</li>
	</ul>
</div>

<div>
	<h2>
		Thursday, June 13
	</h2>
	
	<a name="chemistryII" id="chemistryII"></a>
	<strong>Chemistry II (Chair: Becky Alexander, U. Washington)</strong>
	<ul>
	    <li>
			Joint inversion of formaldehyde and isoprene to constrain non-methane VOC emissions (Jinkyul Choi, CU Boulder)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1Gj9mPCrCGvb_HbvPcuJBkimUGvTHxY2k/view?usp=drive_link">A vertically-resolved canopy significantly improves chemical transport model predictions of ozone deposition to north temperate forests</a> (Michael Vermeuel, U. Minnesota)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/14lzyXChC_pI1blCtdDbIcTHCAMSawBsw/view?usp=drive_link">Assessing the role of RO2 accretion reactions in SOA formation</a> (Alfred Mayhew, U. Utah)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1SiCy6nPrUFOZF2kkw4N4AH9qyf53m5wM/view?usp=drive_link">Evaluation of formaldehyde (HCHO) diurnal variability over North America using Pandonia Global Network (PGN)</a> (Tianlang Zhao, U. Alaska Fairbanks)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1k07wsJk6IO2TytaaRB1hi7lyWq-ynW2L/view?usp=drive_link">Global chemical impacts of furanoids: model analysis and constraints from in-situ observations</a> (Lixu Jin, U. Montana)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1BO7cML3ErP8xzuUks4L_k-5MI8CRDdjH/view?usp=drive_link">GEOS-Chem Adjoint as a decision support tool in Europe</a> (Yixuan Gu, CU Boulder)
		</li>
	</ul>
	
	<a name="fires" id="fires"></a>
	<strong>Fires (Chair: Jingqiu Mao, U. Alaska Fairbanks)</strong>
	<ul>
	    <li>
			The impact of smoke PM on ozone photochemical regimes (Jiaqi Shen, Rutgers)
		</li>
		<li>
			Drivers of smoke air quality in the western United States from 1992 to 2020: natural variability and anthropogenic climate change (Xu Feng, Harvard)
		</li>
		<li>
			Global PM2.5 exposure and health impacts from 2023 Canada extreme wildfire (Yuexuanzi Wang, Tsinghua)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1BKeJgdySoErNRCVOimlGVBeif-pFgoMa/view?usp=drive_link">Influence of model resolution on wildfire impact</a> (Anas Ali, U. Toronto)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1uuTWke6iSTrAOHmrqd1Wdk4Qt1BxYHqS/view?usp=drive_link">When smoke goes up: Effects of biomass burning plume injection height in GEOS-Chem-TOMAS</a> (Nicole June, Colorado State U.)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1S7o7OKsto0tTDTxGqOnG_EiwFNPMl5vb/view?usp=drive_link">Assessing wildfire emissions of CO using 4D-Var inverse modelling</a> (Olalekan Balogun, U. Toronto)
		</li>
	</ul>
	
	<a name="carbon" id="carbon"></a>
	<strong>Carbon gases (Chair: Prasad Kasibhatla, Duke)</strong>
	<ul>
	    <li>
			<a href="https://drive.google.com/file/d/1ned3n4Vf691AhokhDNT6JZpi7wfs46x-/view?usp=drive_link">KEYNOTE: GEOS Modeling in Support of the U.S. Greenhouse Gas Center: Challenges and opportunities in stakeholder-driven product development</a> (Lesley Ott, NASA GSFC)
		</li>
		<li>
			Inverse modeling of satellite methane and in-situ carbon isotopic observations shows that inundation of the wet tropics drove the 2020-2022 methane surge (Zhen Qu, North Carolina State U.)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1Oeji6_adO3DLE-VaIKbwWrTQtAYgImWw/view?usp=drive_link">Interpreting the seasonality of atmospheric methane</a> (James East, Harvard)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1hGFHBJc-9vN1k4P5Swp4wl-lQwXo2xZg/view?usp=drive_link">Quantifying urban and landfill methane emissions in the US using inverse modeling of TROPOMI data at 12 km resolution</a> (Xiaolin Wang, Harvard)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1nI22ylJ2h8qWBkeaR5G8xHfC_257tK-M/view?usp=drive_link">Analytical estimation of carbon dioxide fluxes and information content from OCO-2 satellite data</a> (Hannah Nesser, JPL)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1DIeAFwj4HcfYWHJIcKB1rGytxLn_75g6/view?usp=drive_link">Observation-based assessment of China's methane emissions</a> (Yuzhong Zhang, Westlake)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1fymd7-3cwYVo5NGJCvHPZ3jykkwyR0Km/view?usp=drive_link">Stratospheric methane in GEOS-Chem and its implications for inversions</a> (Todd Mooring, Harvard)
		</li>
	</ul>

	<a name="thu_wg" id="thu_wg"></a>
	<strong>Working Group Breakouts</strong>
	<ul>
	    <li>
			Chemistry Working Group (chairs: Barron Henderson, US EPA; Lu Hu, U. Montana)
		</li>
		<li>
			Adjoint Model and Data Assimilation Working Group (chairs: Daven Henze, U. Colorado; Jun Wang, U. Iowa)
		</li>
		<li>
			Software engineering Working Group (chairs: Lizzie Lundgren, Harvard; Melissa Sulprizio, Harvard; Bob Yantosca, Harvard)
		</li>
	</ul>
		
	<a name="thu_posters" id="thu_posters"></a>
	<strong>Posters</strong>
	<ul>
	    <li>Impacts of Aromatic Chemistry on the Global Atmosphere (Stephen MacFarlane, U. Wollongong)</li>
	    <li>Investigating the combined constraints on isoprene emissions from satellite observations of isoprene, HCHO, and NO2 (Uzzal Kumar Dash, U. Minnesota)</li>
	    <li>Investigating the role of marine aerosols in the critical stratocumulus region over the Southeast Atlantic ocean (Mashiat Hossain, UIUC)</li>
	    <li>Size-resolved and seasonal aerosol depletion of chlorine and bromine in Bermuda during BLEACH (Alli Moon, U. Washington)</li>
	    <li>Assessing GEOS-Chem representation of regional and long-range transport of VOCs using observations from the Mount Bachelor Observatory, OR (Wade Permar, U. Montana)</li>
	    <li>Unintended consequences of enhanced atmospheric methane oxidation (Hannah Horowitz, UIUC)</li>
	    <li>Evaluating OH, O3, and PAN in Biomass Burning Plumes: Insights from MCM and GEOS-Chem Mechanisms (Lu Hu, U Montana)</li>
	    <li>Contribution of biomass burning to North American air quality from 2000-2022 using satellites, GEOS-Chem and ground-based observations (Aaron van Donkelaar, WashU)</li>
	    <li>Assessing wildfire-induced ozone production across scales (Joe Palmo, MIT)</li>
	    <li>Biomass Burning – A comparative study between ACE-FTS observations and the GEOS-Chem High Performance Model (Kevin Bloxam, U. Toronto)</li>
	    <li>Investigating the effects of combustion phase on modeled wildland fire plume vertical distribution and air quality (Soroush Neyestani, UC Riverside)</li>
	    <li>Evaluating Cross track Infrared Sounder (CrIS) retrievals of Volatile Organic Compounds (VOCs) in wildfire smoke plumes using aircraft observations and GEOS-Chem model output (Julieta Juncosa Calahorrano, U. Minnesota)</li>
	    <li>Constraining vertical distribution of aerosols in GEOS-Chem: estimation of surface PM2.5 during wildfire events over continental United States and Canada (Inderjeet Singh, WashU)</li>
	    <li>Simulating stratospheric halogen partitioning in the 2020-2021 Australian wildfire plume (Will Julstrom, U. Iowa)</li>
	    <li>Detecting and quantifying wildfire VOCs using airborne remote sensing (Chengyuan Hu, U. Minnesota)</li>
	    <li>Quantifying CO emissions from boreal wildfires using CHEEREIO with TROPOMI and TCCON data (Dylan Jones, U. Toronto)</li>
	    <li>Quantifying the global methane budget based on TROPOMI satellite measurements (Xueying Yu, Stanford)</li>
	    <li>Inferring global methane emissions from blended TROPOMI+GOSAT observations using the Integrated Methane Inversion (IMI) (Megan He, Harvard)</li>
	    <li>Evaluation of a new high-resolution gridded inventory of methane for New York State in GEOS-Chem using surface and satellite measurements (Matt Loman, U. Rochester)</li>
	    <li>Leveraging chlorine for reassessment of the global methane budget at and since the Last Glacial Maximum (Xin Tie, U. Rochester)</li>
	    <li>Inferring global methane emissions from an ensemble Kalman filter at weekly 2°x2.5° degree resolution using TROPOMI observations (Drew Pendergrass, Harvard)</li>
	</ul>
</div>

<div>
	<h2>
		Friday, June 14
	</h2>
	
	<a name="wg" id="wg"></a>
	<strong>GEOS-Chem Working Group Priorities (chair: Randall Martin, WashU)</strong>
	<ul>
	    <li>
			<a href="https://drive.google.com/file/d/14BzRDDfX2iiI1v0RF8R-qD8w0vuYuF1i/view?usp=drive_link">Emissions</a> (Eloise Marais, U. College London)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1Qum_f2TUZqINATIBkljzm7jAqokBmyE0/view?usp=drive_link">Chemistry</a> (Lu Hu, U. Montana)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1qivKd_yWOWQfOp6rKF4VZkdgJGVv22uO/view?usp=drive_link">Aerosols</a> (Becky Alexander, U. Washington)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1_rH1T29imPifCQSt9ax_-_El18j-RI1q/view?usp=drive_link">Chemistry-climate</a> (Lee Murray, U. Rochester)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/16_VmTZ_eSGv3aEC9cC7fSd5spANq0sW4/view?usp=drive_link">Model adjoint and data assimilation</a> (Daven Henze, CU Boulder)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/19Q6duIwhvlP4NYHSEjzLm1Ht89ufC98H/view?usp=drive_link">Transport</a> (Katie Travis, NASA LaRC)
		</li>
		<li>
			Surface-atmosphere exchange (Amos Tai, Chinese U. Hong Kong)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/10TpPbbF0fl3BIubHrczorGe4Q_fi3QFA/view?usp=drive_link">Carbon gases</a> (Dylan Jones, U. Toronto)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1TUn1MnGnZok6OpOU6aZ60wIXj2SGIZ7W/view?usp=drive_link">Software engineering</a> (Bob Yantosca, Harvard)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1h4IdSyptg5I3q-_-mDFYC6TFQPUWE15g/view?usp=drive_link">Mercury and POPs</a> (Viral Shah, NASA GMAO)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1SKp99tJb_dGXU-bUIUy_JXRyH1wMwXv_/view?usp=drive_link">Stratosphere</a> (Dylan Jones, U. Toronto)
		</li>
	</ul>
	
	<a name="future" id="future"></a>
	<strong>Looking ahead (Chair: Randall Martin, WashU)</strong>
    <ul>
		<li>
			<a href="https://drive.google.com/file/d/1ZJM1zk4azcZmSQCuzdbb7fMrlKf99i9m/view?usp=drive_link">Potential GEOS-Chem contributions to CMIP7</a> (Lee Murray, U. Rochester)
		</li>
		<li>
			<a href="https://drive.google.com/file/d/1MMLRhveVE6fq-63dVCKH6KaIvobtB-CC/view?usp=drive_link">Open discussion on GEOS-Chem priorities</a> (Randall Martin, WashU, discussion lead)
		</li>
	</ul>
</div>

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