Read more about each presentation below
- Keynote: Linking Data with Decision-Making for Air Quality
- Keynote: Pathways to advance wildfire smoke predictions
- Breakthrough Innovations in Atmospheric & Air Quality Modeling
- Composition and Operational Forecasting from Daily to Seasonal Scales
- M3: Merging Measurements & Models
- Meteorology-Chemistry Coupling, Feedbacks, and Interactions
- Modeling of Processes Across Multiple Scales
- Unique/Extreme Events and their Impacts on Meteorology and Air Quality
- Poster Presentations
Click here to view the full 2023 Program PDF.
Keynote: Linking Data with Decision-Making for Air Quality
Tracey Holloway, University of Wisconsin, Madison
Environmental managers have long relied on atmospheric models and in situ measurements to support decision-making under the Clean Air Act. Today an even wider audience of policy, planning, and advocacy organizations are interested in air quality data to support climate action, environmental justice, emergency response, and other decision needs. By collaborating with these user communities, atmospheric scientists can expand the impact of existing knowledge, data, and tools. Growing the impact of science is the core mission of the NASA Health and Air Quality Applied Sciences Team, a major science applications and engagement effort over the past 10 years. Lessons learned from leading this NASA team will be discussed, and extended to broader applications of atmospheric models for applied problem-solving. Atmospheric models play an important role interpreting satellite data, connecting emissions and impacts, and answering “what if?” questions relevant to policy and planning. Traditional scientific frameworks are evolving to better support engagement and to expand the benefits of science to new issues and communities. Still, challenges remain, especially for early-career scientists balancing academic milestones with “real-world” engagement and societal impact.
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Keynote: Pathways to advance wildfire smoke predictions
Pablo Saide, UCLA
Smoke from biomass burning can generate a variety of impacts, including visibility issues, negative health effects on population, and meteorology and climate change effects. Air quality models can be used to predict smoke and its impacts; however, they can be highly uncertain. This presentation will show recent work identifying some of the existing gaps affecting predictions including topics of smoke emissions, vertical distribution, and aging. Observational evidence from ground-based networks, satellite retrievals and airborne field campaign data are heavily used, including the development of new derived products, and evaluation of novel observations. Potential pathways for model improvement will be shown and discussed.
Recording of Presentation Presentation PDF
Breakthrough Innovations in Atmospheric & Air Quality Modeling
Ending the half-a-century monopoly of similarity functions in boundary layer modeling
Kiran Alapaty, US EPA
For the past half century similarity functions have been widely used as universal functions in surface layer modeling. Proliferation of similarity functions has contributed to development of several surface and boundary layer formulations which in turn have contributed to differences in the outcomes among different 3-D atmospheric models. 0-D (box) models that are driven by field-scale measurements don’t require similarity functions since field measurements provide natural variability of atmosphere. However, similarity functions are necessary to accurately model predictions of boundary layer evolution and associated processes in 3-D models. Thus, 0-D and 3-D model formulations differ in representing boundary layer processes. To address these modeling issues, we developed a seamless universal formulation for use in 0-D as well as 3-D atmospheric models. This innovative methodology avoids the usage of similarity functions and can unify all types of models.
The basis of the new methodology is the (1) development of a 3-D turbulence velocity scale which is parameterized using the surface turbulence kinetic energy and (2) evaluation using field scale measurements. The new methodology has been tested and validated using relevant other measurements and meteorological and air quality models. Preliminary results indicate that the new methodology is as accurate as those using similarity functions, and thus may serve to replace the use of similarity functions.
GPU Assisted Computation for a Gas Phase Chemical Solver in CMAQ
Cesunica Ivey, University of California Berkeley
In recent versions of the Community Multiscale Air Quality (CMAQ) model, the gas phase chemical solver has been identified as one of the bottleneck modules. Here we the explore use of graphical processing units (GPUs) to reduce CMAQ runtime. The GPU modification included the rewriting of the SAPRC07 gas phase module for compatibility with CUDA GPU processors and libraries. The GPU-compatible module was run in series with the other science modules, for which the CPU-based code was maintained. We evaluated precision of the GPU modification by calculating GPU model error for ozone concentrations for a 4-km southern California simulation. While the runtime of individual GPU-modified operations decreased, data transfer limitations penalized overall computational efficiency. We posit that improvements in data transfer hardware will assist with overall efficiency improvements.
Spatiotemporal estimates of surface PM2.5 concentrations in the western U.S. using NASA MODIS and VIIRS retrievals, data fusion, and Machine Learning techniques
Marcela Loria-Salazar, School of Meteorology, University of Oklahoma
Previous investigations have used satellite remote sensing to estimate surface air pollution concentrations. However, air quality models are not robust in the western U.S. due to specific regional characteristics. This investigation uses ML gap-filled AOD satellite retrievals from the MODIS and VIIRS instruments as a spatial predictor of PM2.5. The data fusion model incorporates high-resolution simulated weather variables from the WRF model, emissions inventory data from NEI, elevation, population density, land cover information, and gap-filled aerosol optical depth from MODIS and VIIRS as covariates that can vary in space and time. Based on our previous research, the covariates were selected to account for complex atmospheric physics and meteorological phenomena that govern aerosol transport in mountainous regions. It is expected that by selecting high-resolution, temporally resolved physics and emissions variables as covariates, the surface PM2.5 concentration estimates in the data fusion model will be improved for the western U.S. from 2012-2013. Our results show satellite-derived PM2.5 R~0.65, RMSE~7.8)and CMAQ-derived PM2.5 R~0.66. The challenge with the AOD-derived PM2.5 model is that no estimates could be made at locations with no AOD retrieval, and the CMAQ -derived PM2.5 model could not capture the up/downwind smoke transport. Using gap-filled AOD remedied this problem, as the PM2.5 exposure model shows the transport of the smoke with no spatial gaps.
Chemistry in the twilight zone: a species-level assessment of numerical stiffness
Obin Sturm, University of Southern California
The Goddard Earth Observing System Composition Forecast (GEOS-CF) produces high resolution, global predictions of atmospheric chemical constituents using the GEOS-Chem chemistry module. Due to high resolution and chemical detail, GEOS-CF forecasts are computationally demanding and take a large amount of high performance computing time and resources. We identify speedup potential in the reduction of the load imbalance in chemistry calculations. Load imbalances are primarily driven by chemistry calculations in twilight regions as grid cells far from chemical pseudo-equilibrium transition to new regimes. We identify chemical species that contribute most to the computational cost of the chemical integration. We develop an approach to customize the tolerances of these “stiff” species in the chemical integrator to accelerate simulations by reducing the number of internal integration time steps required for convergence. By applying these methods to stratospheric chemistry at twilight, we can reduce the load imbalance across CPUs in 3D simulations and accelerate simulations without significant changes in the simulated concentrations of key species.
Online Machine Learning Chemical Solver for Fast, Stable Long-Term Global Simulations of Atmospheric Chemistry
Makoto Kelp, Stanford University
Global models of atmospheric chemistry are computationally expensive. A bottleneck is the chemical solver that integrates the large-dimensional coupled systems of kinetic equations describing the chemical mechanism. Machine learning (ML) could be transformative for reducing the cost of an atmospheric chemistry simulation by replacing the chemical solver with a faster emulator. However, past work found that ML chemical solvers experience rapid error growth and become unstable over time. Here, we present results achieving for the first time a stable full-year global simulation of atmospheric chemistry with 3 months seasonal ML solvers and with five-fold speedup in computational performance over the reference simulation. We show that online training of the ML solver synchronously with the atmospheric chemistry model simulation produces considerably more stable results than offline training from a static data set of simulation results. Although our work represents an important step for using ML solvers in global atmospheric chemistry models, more work is needed to extend it to large chemical mechanisms and to reduce errors during long-term chemical aging.
Efficient multiscale weather modeling of the atmospheric boundary layer with NCAR’s GPU-resident model FastEddy®
Domingo Muñoz-Esparza, National Center for Atmospheric Research (NCAR)
One of the largest uncertainties in modeling the atmosphere arises from deficiencies in parametrizing complex microscale processes that typically occur at the sub-grid scale in numerical weather prediction (NWP) models. Explicit representation of microscale turbulence provides an attractive alternative toward accurate weather modeling in general, and of atmospheric boundary layer (ABL) phenomena in particular. However, the prohibitive computational cost of performing large-eddy simulations (LESs) has relegated this type of modeling approach to fundamental research over idealized scenarios. In this talk we will provide an overview of the efforts carried out by the Research Applications Laboratory at the National Center for Atmospheric Research (NCAR) to develop and utilize a computationally efficient modeling framework tailored for multiscale weather prediction in the ABL. This modeling capability couples two NCAR models: the Weather Research and Forecasting (WRF) model for mesoscale predictions (km-scale grid spacing) with the GPU-resident FastEddy® LES model (meter-scale grid spacing) to enable accurate microscale forecasting within the ABL. Examples will be discussed that highlight the dynamic and heterogeneous weather conditions that occur within the ABL, including flows over complex terrain and within the urban environment, and that cannot be appropriately captured with current routine NWP models at kilometer-scale.
Composition and Operational Forecasting from Daily to Seasonal Scales
Real-time simulations of smoke and dust by NOAA's Rapid Refresh Forecasting System
Ravan Ahmadov, NOAA/GSL
NOAA Global Systems Laboratory in collaboration with other laboratories has been adding smoke and dust components to the experimental Rapid Refresh Forecasting (RRFS) numerical weather prediction model. The experimental RRFS-Smoke/Dust (RRFS-SD) modeling system estimates wildland fire emissions in real-time by ingesting the hourly fire radiative energy from the Regional ABI, and VIIRS fire Emissions satellite based dataset. In the model fire plume rise is estimated by using the satellite based fire radiative power data. Additionally the model includes a dust parameterization to simulate dust fluxes in real time.
The RRFS-SD model simulates advection, turbulent mixing, dry and wet deposition of smoke (primary PM2.5), and dust (fine and coarse modes) aerosol species. The gravitational settling of the coarse dust particles is also included in the model. The RRFS-SD model grid covers the CONUS domain at 3km spatial resolution. The model is simulated in real time on an hourly cycle, whereas every 6th cycle goes out to 60 hours.
This presentation discusses the new smoke and dust forecasting model. Evaluation of the real-time and retrospective smoke and dust simulations by RRFS-SD will be presented as well.
Quasi-Realtime/Operational Forecasting/Assimilation/Emissions Estimation for Tropospheric Atmospheric Composition (Including All Criteria Pollutants)
Arthur Mizzi, NASA Ames Research Center, NOAA Chemical Systems Laboratory, and University of Colorado at Boulder Mechanical Engineering
We are using WRF-Chem/DART to explore quasi-operational ensemble atmospheric composition (AC) forecasting/assimilation/emissions estimation. We have two applications: (i) a medium resolution (15 km x 15 km) setup that is applied to the Front Range Air Pollution and Photochemistry Experiment (FRAPPE) and a high resolution (4 km x 4 km) setup that is applied to the State of Colorado (COLORADO). We jointly assimilate: (i) conventional meteorological observations; (ii) EPA Air Quality System (AQS) measurements of carbon monoxide (CO), ozone (O3), nitrogen dioxide (NO2), sulfur dioxide (SO2), particulate matter (PM) with diameters less that 10 µm, (PM10), and PM with diameters less than 2.5 µm (PM2.5); and (iii) MOPITT, IASI, MODIS, OMI, TROPOMI, and proxy TEMPO total/partial column and/or profile retrievals of CO, O3, NO2, SO2, and AOD.
We use the assimilated observations to constrain the concentrations and emissions for all criteria pollutants. We validate the FRAPPE results against independent FRAPPE measurements but do not have validation data for the COLORADO results. We use this latter application to study the resolution dependencies of joint assimilation and emissions estimation. The proxy TEMPO observations are assimilated as ‘actual observations’ to study the impacts of geostationary trace gas observations on AC forecasting/emissions estimation. We will present our results and a summary of our experience with TEMPO observations.
Forecasting the occurrence of severe haze events: A deep learning approach
Chien Wang, LAERO, CNRS/UPS
Severe haze formed by particulate pollution can interrupt economic and societal activities, threat human health, thus impose substantial economic loss. Forecasting the occurrence of this high impact event could allow mitigation measures to be implemented ahead of time thus effectively minimize the economic loss. Nevertheless, this task remains a challenge for current deterministic models due to issues in making accurate predictions of both meteorology and atmospheric compositions. As an alternative approach, a deep convolutional neural network (CNN) containing about one million neurons and 20 million parameters, namely HazeNet, has been developed to forecast hazes in Singapore, Beijing, Shanghai, and now Paris. Deep learning directly connects raw input data with the output through CNNs, providing an “end-to-end” solution that could benefit the efforts in forecasting poorly known extreme events such as haze. Trained using time sequential regional maps of 16 to 18 meteorological and hydrological variables alongside surface visibility data over the past 46 years, the machine has achieved an impressive performance in identifying the haze events and their favorite weather and hydrological conditions. Here, I will discuss the design, training, and validation alongside the performance of the HazeNet in forecasting haze events in Paris, using a new architecture that can better recognize characteristic spatial scales associated with different meteorological and hydrological features.
Evaluation and Application of the NCAR CONUS Air Quality Research Forecasting System
Gabriele Pfister, National Center for Atmospheric Research (NCAR)
We present the performance and applications of a research air quality forecasting system over the contiguous United States (CONUS). The system has been developed to support community model development, allow early identification of model errors and biases, support the atmospheric science community in their research, and assist field campaign planning and air quality decision-making. The forecasts are an experimental research project and aim to complement the NOAA operational air quality forecasts. The system is based on the WRF-Chem model and was started in June 2019, producing a 2-day forecast every day at 12 km x 12 km over CONUS. In June 2020 a second forecast has been added which utilizes updated emissions and chemistry a higher resolution (4 km x 4 km) Colorado domain. The system was extended in 2022 by a third product which provides meteorology-only forecasts at 1.3 km x 1.3 km resolution over the Northern Colorado Front Range. We will report on the applications of the forecasting system and on the spatial and temporal performance of the forecasts with a specific focus on surface ozone. Further, we will show results from sensitivity studies to help understand the origin of model biases including the sensitivity to emissions, boundary conditions and model physics. We will also discuss to what degree the application of an urban canopy model improves the simulations of the urban heat island effect and associated changes in surface ozone.
Next-Generation Air Quality Predictions for the United States in the Unified Forecast System
Ivanka Stajner, NOAA/NWS/NCEP/EMC
NOAA is developing the next generation air quality (AQ) prediction system for the United States (U.S.) within the Unified Forecast System (UFS) framework. The goal is to improve forecast guidance for air quality and in particular to better represent and forecast impacts of wildfires on AQ. This new UFS-AQM system consists of a new regional UFS weather model is online coupled with chemistry represented by the EPA’s Community Multiscale AQ (CMAQ) modeling system with Carbon Bond VI and AERO6 mechanisms. Anthropogenic emissions are based on EPA’s National Emissions Inventories over CONUS and global inventories elsewhere. Wildfire emissions are specified by the NESDIS Regional Hourly Advanced Baseline Imager (ABI) and Visible Infrared Imaging Radiometer Suite (VIIRS) Emissions (RAVE). Lateral boundary conditions for aerosols are provided by the Global Ensemble Forecast System with the Goddard Chemistry Aerosol Radiation and Transport (GOCART) module. UFS-AQM is being tested over a regional domain covering CONUS, Alaska and Hawaii. The initial evaluation of UFS-AQM used Fire Influence on Regional to Global Environments and AQ (FIREX-AQ) field data and routine AQ measurements. UFS-AQM includes plume rise for wildfire smoke and for point source emissions. A bias correction post-processing procedure was developed for UFS-AQM to improve prediction accuracy. Data assimilation of fine particulate matter (PM2.5) observations from AirNow, Aerosol Optical Depth (AOD) retrievals from VIIRS and NO2 retrievals from the TROPOspheric Monitoring Instrument (TROPOMI) is being developed and tested in UFS-AQM to constrain pollutant concentrations.
Longer term plans for AQ prediction include increased resolution consistent with the Rapid Refresh Forecast System (RRFS) under development and aerosol lateral boundary conditions from a 6-way coupled atmosphere - ocean - land - sea-ice - waves - aerosols global UFS system under development. A machine learning emulator is being developed to improve computational efficiency for prediction of chemical transformations and tracer transport in UFS-AQM at high resolution.
Recent Developments in ECCC’s Regional Air Quality Deterministic Prediction System
Craig Stroud, Environment and Climate Change Canada (ECCC)
Environment and Climate Change Canada (ECCC) coordinates an ongoing North American air quality forecasting multi-model verification. In this verification, the forecast skill of ECCC’s GEM-MACH model (Global Environmental Multiscale – Model of Atmospheric Chemistry) is compared against four peer model systems (CMAQ, IFS-CAMS, GEOS-CF, IFS-SILAM) . In this presentation, we will start by showing GEM-MACH’s recent model performance in the multi-model verification. We will then show results of a diagnostic evaluation using the full suite of network measurements for 2016 and year-specific emissions for 2016. The evaluation was used to identify a list of model developments: 1) updated chemical lateral boundary conditions, 2) improved spatial surrogates for residential wood combustion emissions and other area source and off-road emissions, 3) processes enhancing near surface mixing, 4) a series of advances related to biogenic emissions and forest canopy processes, and finally 6) addition of a wildfire PM2.5 proxy. Progress towards these model advances in the current ECCC Innovation Cycle will be presented.
M3: Merging Measurements & Models
A data fusion model for rapid wildfire smoke exposure estimates using routinely-available data
Sean Raffuse, UC Davis Air Quality Research Center
Urban smoke exposure events from large wildfires have become increasingly common in California and throughout the western United States. The ability to study the impacts of high smoke aerosol exposures from these events on the public is limited by the availability of high-quality, spatially-resolved estimates of aerosol concentrations. Methods for assigning aerosol exposure often employ multiple data sets that are time consuming and expensive to create and difficult to reproduce. As these events have gone from occasional to nearly annual in frequency, the need for rapid smoke exposure assessments has increased. The rapidfire R package provides a suite of tools for developing exposure assignments using data sets that are routinely generated and publicly available within a month of the event. Specifically, rapidfire harvests official air quality monitoring, satellite observations, meteorological modeling, operational predictive smoke modeling, and low-cost sensor networks. A machine learning approach is used to fuse the different data sets. Using rapidfire, we produced estimates of ground-level 24-hour average PM2.5 over for several large wildfire smoke events in California from 2017-2021. These estimates show excellent agreement with independent measures of PM2.5 from filter-based networks.
Flash frequency parameterization insights from the Geostationary Lightning Mapper
Jonathan Wynn Smith, NOAA/GFDL
To quantify the seasonal lightning flash frequency (ff), we compare the novel GOES-16 (G16) and -17 (G17) Geostationary Lightning Mappers (GLMs) ff (flashes/km2/second) observations to GFDL global climate model (GCM) flash frequency output. Through these comparisons we quantify model parameterization and observational biases. These biases will inform model development of existing and new ff parameterizations in the GFDL GCMs. In order to develop lightning-nitrogen oxide parameterizations and refine estimates of tropospheric ozone and methane within the GFDL GCMs, we will evaluate other lightning and atmospheric chemistry datasets. Initially, comparisons suggest that observed ffs in both GLMs (160°E-20°W and ±55°N/S) are 2-3 orders of magnitude greater than the cloud top height (CTH) ffs parameterization estimates in the GFDL Atmospheric Model version 4 (AM4). The G16 GLM (130-20°W and ±55°N/S) flash rates (total flashes per second) are within 2-16% of the CTH simulation. While G17 GLM (160°E-70°W and ±55°N/S) has flash rates of 2-4 times less than the model, correlations were greater than 0.5 for both the land model grids and for all of the model grids in DJF and JJA. Comparing G16 GLM flash frequency to the multiplication of ERA5 convective available potential energy (CAPE) and total precipitation rate developed by Romps et al. (2014) produces correlations greater than 0.6. This study will analyze other ff parameterizations such as cloud water path and ice mass flux.
Spatial Resolved Surface Ozone with Urban and Rural Differentiation during 1990–2019: A Space–Time Bayesian Neural Network Downscaler
Haitong Sun, University of Cambridge
Long-term exposure to ambient ozone (O3) can lead to a series of chronic diseases and associated premature deaths, and thus population-level environmental health studies hanker after the high-resolution surface O3 concentration database. In response to this demand, we innovatively construct a space–time Bayesian neural network parametric regressor to fuse TOAR historical observations, CMIP6 multimodel simulation ensemble, population distributions, land cover properties, and emission inventories altogether and downscale to 10 km × 10 km spatial resolution with high methodological reliability. Using CMIP6 model simulations directly without urban–rural differentiation will lead to underestimations of population O3 exposure by 2.0±0.8 ppbV averaged over each historical year.
The MELODIES MONET Atmospheric Composition Diagnostics Package
David Fillmore, NCAR
MELODIES MONET is a Python package that systematically compares model output with observations, providing the community with a valuable tool to reproducibly evaluate simulated atmospheric chemistry. It is a dual effort between NCAR and NOAA, developed through combining the project MELODIES (Model Evaluation using Observations, Diagnostics and Experiments Software) with the initial Python framework from MONET (Model and Observation Evaluation Toolkit) for surface measurement comparisons. The core functionality of the package includes the spatial and temporal alignment of a diverse set of model and observational datasets, including observations from surface networks, aircraft, and Earth orbiting satellites. In addition to a standard suite of spatial pattern and time series plots, MELODIES MONET generates a set of statistical metrics, and is designed to be both highly extensible and customizable, with, for instance, data science modules such as Scikit-Learn and Scipy.
In this presentation we give an overview of the essential package functionality, and include several examples for exploring air quality data. We also discuss how MELODIES MONET is being integrated into NCAR model evaluations and NOAA operations, including coupling to other software such as the Model Evaluation Tools (MET) and the Joint Effort for Data assimilation Integration (JEDI) being developed by the Joint Center for Satellite Data Assimilation (JCSDA).
Recording of Presentation Presentation PDF
Quantifying Sources of Transported and Background Atmospheric Pollutants to California Part I: Model Evaluations for 2017-2021
Yuyan Cui, California Air Resources Board
Accurate diagnosis of non-local sources and chemical background to California’s air quality is essential. In this study, we utilized three-dimensional global chemical modeling to diagnose these sources, their quantities, and changes over time. We conducted and evaluated five-year (2017-2021) GEOS-Chem simulations using various observing systems and assessed simulations of near-surface PM2.5 species using ground-based monitoring networks including IMPROVE (rural) and CSN (urban). The results show that GEOS-Chem captured the annual-trend of surface total PM2.5 by season, with a low bias for the Western US and good agreement for the Middle/Eastern US. GEOS-Chem underestimated elemental and organic carbons for CSN sites, especially organic carbons in the Western US during winter and spring. Nevertheless, the model showed a smaller model-data mismatch for carbonaceous aerosols at the IMPROVE sites. The model overestimated ammonium and nitrate for both IMPROVE and CSN sites in the Middle/Eastern US across four seasons. For the Western US, it overestimated ammonium and nitrate for IMPROVE sites and underestimated for CSN sites during winter. GEOS-Chem captured sulfate well, but it slightly overestimated for IMPROVE sites during winter. Additionally, we are assessing simulations of O3 and NO2 during the five years. GEOS-Chem simulated daytime surface ozone well in the Western US. Furthermore, we also compared GEOS-Chem and CAM-chem simulations for 2017-2020.
Recording of Presentation Presentation PDF
Atmospheric composition reanalysis
Kazuyuki Miyazaki, NASA JPL
Providing accurate global estimates of atmospheric composition is essential to evaluate its impact on climate and air quality, which in turn will help environmental policy making. However, our current knowledge of atmospheric composition is limited by insufficient information from the current observing systems. Chemical data assimilation (DA) has made substantial progress in reproducing regional and global atmospheric composition and its attributions, including estimates of anthropogenic and natural emissions of air pollutants. Atmospheric composition (or chemical) reanalysis is a systematic approach that uses DA techniques to produce a long-term data record of atmospheric composition consistent with model processes and observations. Atmospheric composition reanalysis has made considerable progress in recent years and provides unique global coverage of decadal trends during the satellite data records for studies of atmospheric composition variability. The recent reanalysis also provides emission information, which can provide a test of the efficacy of emissions controls. Meanwhile, the new capability of satellite instruments has great potential to constrain detailed spatial and temporal patterns for various species. This talk will provide an overview of recent progress in chemical reanalysis efforts, including the chemical reanalysis inter-comparison project.
1km-resolution, multi-species (pm2.5, no2, o3) surface air pollution by machine learning data fusion: effects of surface observation sparsity, and inclusion of GEMS geostationary satellite fields over Korea
Beiming Tang, University of Iowa and George Mason University
Additional Authors: Gregory Carmichael, Charles Stanier, Meng Gao, Daniel Tong, Barry Baker
Exposure to ambient air pollution causes up to 4 million deaths annually, with a large fraction of those in developing countries. However, observation stations are scarce in many developing countries. To analyze and prevent air pollution related disease, flexible tools are needed for estimation of major pollutants through fusion of available local observations, global and regional chemical transport model (CTM) simulations, and both geostationary and polar-orbiting satellite products.We present a machine learning fusion approach to estimate fine particulate matter (PM2.5), ozone, nitrogen dioxide (NO2), and black carbon (BC) concentrations at fine resolution (1km x 1km) for regions lacking extensive ground station observations. Novel features of the model are that we report relative performance for use of coarse global reanalysis (CAMS) vs. 4-km regional CTM modeling with WRF-Chem. And we report relative performance for PM2.5 both with and without GEMS.
We develop and test the model in a relatively data-dense location (Korea) and test the robustness to reduced observational data through progressive data denial.The random forest machine learning approach is tested for May 2016 and May 2021, (to allow incorporation of GEMS). We demonstrate extension to relatively data-poor regions through tests of Vietnam, where there is a strong need for air pollution exposure estimates for health studies, but very few surface observations.
Meteorology-Chemistry Coupling, Feedbacks, and Interactions
Biomass Burning Aerosols Effects on Rainfall Characteristics and Cloud formation over West Africa
NJIE Teeda, Federal University of Technology, Akure, Nigeria.
This study evaluate the capability of the regional climate model (Wrf-Chem) on capturing Biomass Burning Aerosols (BBA) effect on monsoon rainfall and determining the influence of BBA on rainfall characteristics and cloud formation. Two simulations were run for a period of six months (March-August) in 2012 over West Africa. The first simulation was run with radiative effect of BBA turn off (ONRad) while the second was run with radiative effect of BBA turn on (ORad). The model’s precipitation (convective and non-convective) and the total precipitation (sum of convective and non-convective) were evaluated against observational precipitation. Also, the Outgoing longwave radiation (OLR) from Wrf-Chem output (ONRad and ORad) were compared with reanalysis OLR from ERA5. The study found out that Wrf-Chem overestimated the convective, non-convectice and total precipitation with or without BBA radiative effect compared to observe over the study area. The model under estimate the OLR value with or without BBA radiative effect and that BBA radiative effect have increase the rate of convective cloud formation over West Africa.
Characterizing continental-scale OH trends in CESM2-WACCM6 climate model
Qindan Zhu, Massachusetts Institute of Technology
The hydroxyl radical (OH) lies at the nexus of climate and air quality as the primary oxidant for both reactive greenhouse gases and many hazardous air pollutants. The lifetime of methane, the second most important greenhouse gas behind carbon dioxide since the pre-industrial, is largely set by the global integral of OH concentrations, which vary strongly in space and time. To better understand the spatiotemporal dynamics of OH, we utilize an existing 12-member initial-condition ensemble of the CESM2-WACCM6 chemistry-climate coupled model spanning the years 1950 to 2014. We show a substantial spatial variation of historical trends of tropospheric column OH. For instance, the OH trends between 2005 and 2014 ranges from -0.5%/year reduction in North America and +0.2%/year increase in Asia. We then use a machine learning (ML) technique, gradient boosted tree model, to identify the dominant drivers contributing to the variation in these decadal OH trends. Combining climate model simulations with ML, we investigate the sensitivity of OH trends to both chemical and meteorological drivers.
Understanding US Air Quality – Drought Linkages For Seasonal Prediction Potential
Meiyun Lin, NOAA Geophysical Fluid Dynamics Laboratory
Soil moisture drought alters air quality through land-biosphere feedbacks, e.g. reducing O3 removal by vegetation, increasing wildfire and dust emissions, and altering BVOC emissions. Soil moisture has significant predictability on seasonal time scales. To probe seasonal prediction potential of US air quality, we examine the role of SST forcing on continental-scale drought and air quality extremes in a suite of observations and multi-decadal AMIP simulations (1988-2020) with the GFDL variable-resolution global chemistry-climate model (AM4VR). With regional grid refinements of 13 km over the US, AM4VR provides vast improvements upon typical 100 km global models in representing US climate and air quality extremes. We highlight improved representation of the ENSO drought and temperature teleconnections and their impacts on southwest US springtime dustiness and eastern US summer O3 pollution. With interactive dust emissions from land, AM4VR captures observed year-to-year variability of southwest US springtime dustiness, especially enhancements during a negative Pacific Decadal Oscillation and La Niña. For the eastern US, we examine interannual variability in the mean area extent of heat waves and O3 pollution episodes, by considering the 300 worst days from 1990 to 2020. Accounting for reduced O3 removal by drought-stressed vegetation enhances the model's ability to represent O3 pollution extremes, either forced by SST anomalies or arising from internal atmospheric variability.
Local Formation versus Regional Contributions to Secondary Organic Aerosol
Allison Steiner, University of Michigan
Organic aerosols represent a large fraction of the total particulate matter in the atmosphere, and can be formed from primary or secondary anthropogenic or biogenic sources. The contribution of biogenic volatile organic carbon emitted from terrestrial vegetation is a large contributor to secondary organic aerosols near forested regions, though understanding local sources versus the role of regional advection can be challenging to determine based on ground-based measurements alone. Here we combine two modeling approaches to understand how organic aerosol sampled at individual sites can be attributed to either local formation or is influenced by regional atmospheric signatures. We compare two mixed deciduous forests in the United States, including a site in Alabama and one in northern Michigan. We use a one-dimensional canopy-chemistry model to understand local formation of organic aerosol from isoprene and monoterpenes, in conjunction with 3D regional chemistry-meteorology simulations to determine the rate of aerosol advection to the observational sites. This approach can disentangle the contributions from local formation versus regional advection to the organic aerosol burden, with implications for understanding biosphere-atmosphere feedbacks.
Modeling of Processes Across Multiple Scales
Multi-Scale Modeling of Turbulence and Convection: The Eddy-Diffusivity/Mass-Flux (EDMF) Approach
Joao Teixeira, JPL/Caltech and UCLA
Turbulence and convection play a fundamental role in weather, climate, and air quality modeling. However, current atmospheric models cannot explicitly resolve most turbulent and convective flow, which needs to be parameterized. We present and discuss the multi-plume Eddy-Diffusivity/Mass-Flux (EDMF) approach as a unified and multi-scale parameterization. EDMF represents small-scale turbulence with a classic Eddy-Diffusivity (ED) method, and the larger-scale (boundary layer and tropospheric-scale) eddies as multiple plumes using the Mass-Flux (MF) concept. We focus on recent results that highlight the success of this approach in representing boundary layer, shallow, and deep convection in a fully unified manner.
Quantifying the effects of vegetative in-canopy photolysis and turbulence processes on U.S. air quality
Chi-Tsan Wang, George Mason University
Most chemical transport models in the community, such as the Community Multiscale Air Quality (CMAQ) model continue to rely on the approximate, but useful “big-leaf” approach for representing the air-canopy interface, with little to no representation of the underlying vegetative in-canopy processes. Here we employ parameterizations for the effects of in-canopy photolysis attenuation and modulated vertical turbulence/eddy diffusivity in a variant of the George Mason University (GMU) air quality modeling system, which uses CMAQ version 5.3.1 with integrated Process Analysis (PA) output and assessment tools. Preliminary CMAQ results show that the in-canopy processes lead to substantial summer (August 2019) hourly NO2 concentration changes of -5 to 11 ppb in contiguous canopy regions (e.g., Eastern U.S.), with hourly O3 concentration changes between -16 to 12 ppb. The preliminary results of CMAQ-PA quantify more detailed chemical and physical processes for critical species (O3, NOx, HCHO, and PM2.5) changes due to the in-canopy parameterizations. The PA results using an aggregated approach over the planetary boundary layer (PBL) shows that the reduced in-canopy vertical transport (-20%) and photolysis (-70%) rates in the canopy can synergistically increase net NO2 chemical processes (+95%) and decrease odd oxygen formation (-70%). Therefore, the canopy increases the daily average NO2 (+48%) and decreases O3 concentration (-20%) in the PBL.
Large-eddy simulation (LES) of atmospheric chemical and physical processes: from semi-idealized NCAR LES-Chem to realistic WRF-LES-Chem
Yang Li, Baylor University
Vertical mixing and in-cloud processing of volatile organic compounds (VOCs) in the planetary boundary layer (PBL) is very important in simulating the formation of ozone (O3), secondary organic aerosols (SOA), and climate feedbacks. Horizontally, high-resolution modeling of the distribution of these key air pollutants is crucial to support emerging community-level health studies. Our previous semi-idealized applications of the NCAR LES have proven fidelity of the high-resolution turbulence-resolving LES modeling in representing boundary layer and cloud dynamics as well as in reproducing observed vertical profiles of VOCs and oxidants. Taking advantage of the large measurement datasets from the TRacking Aerosol Convection ExpeRiment (TRACER) campaigns, this study extends to the realistic applications of LES within the Weather Research and Forecasting (WRF) model coupled with Chemistry (WRF-LES-Chem) to better represent the chemical and physical processes of VOCs and to interpret O3 formation in Houston, TX. A multi-layer setup that consists of five domains is implemented, with the first three WRF domains representing the mesoscale setup at km resolutions and driving the two innermost LES domains at grid spacings of ~100m. This modeling system effectively links regional- and local-scale process representations, allowing us to examine the change in boundary layer mixing, the shift in VOC chemistry, and the transition of O3-VOC-nitrogen oxides (NOx) sensitivity across scales.
Advancing understanding of land-atmosphere interactions by breaking discipline and scale barriers
Jordi Vilà-Guerau de Arellano, Wageningen University
Vegetation and atmosphere processes are coupled through a myriad of interactions linking plant transpiration, carbon dioxide assimilation, turbulent transport of moisture, heat and atmospheric constituents, aerosol formation, moist convection and precipitation. Advances in our understanding are hampered by discipline barriers and challenges in understanding the role of small spatiotemporal scales. Here, we propose to study the atmosphere-ecosystem interaction as a continuum by integrating leaf to regional scales (multi-scale) and integrating biochemical and physical processes (multi-processes). The challenges ahead are (1)How do clouds and canopies affect the transferring and in-canopy penetration of radiation, thereby impacting photosynthesis and biogenic chemical transformations? (2)How is the radiative energy spatially distributed and converted into heat, moisture, carbon and reactive compounds turbulent fluxes (3) How do local (1 m to kilometers) biochemical and physical processes interact with regional meteorology and atmospheric composition (kilometers to 100 km)? (4)How can we integrate the feedbacks between cloud radiative effects and plant physiology to reduce uncertainties in our climate projections driven by regional warming and enhanced carbon dioxide levels? Our methodology integrates fine-scale explicit simulations with new observational techniques to determine the role of unresolved small-scale spatiotemporal processes in weather and climate models.
Unique/Extreme Events and their Impacts on Meteorology and Air Quality
Modeling the June 2023 Smoke Event over the Northeast United States
Peter Colarco, NASA GSFC
Extensive, early-season biomass burning activity across Canada in May and June 2023 resulted in vast plumes of smoke that impacted air quality and visibility across large parts of the United States. Transport of smoke aloft and at the surface from fires in Quebec in early June significantly degraded air quality (fine particulate matter, PM2.5) between New York City and Washington, D.C. Progress of this event was simulated in the Goddard Earth Observing System (GEOS) global Earth system model. The near-real time configuration of GEOS (so called GEOS-FP) invokes aerosol and meteorological data assimilation to produce global, three-dimensional analyses and forecasts of the weather and aerosol state of the atmosphere. A challenge for such systems though is the lack of real-time information on biomass burning sources. Practically, the GEOS-FP system is using biomass burning emissions derived from fire radiative power observations made by the Moderate Resolution Imaging Spectroradiometer (MODIS) satellite instruments which are: (i) available only under cloud free conditions, (ii) generally valid for the day prior to the forecast initialization, and (iii) assumed to persist over the forecast duration. We systematically investigate the impacts of these limitations on the forecast capabilities of GEOS by performing experiments that test biomass burning emission input assumptions (using day-of-forecast a posteriori “known” biomass burning emissions, day-prior emissions, and persisted emissions) and comparing forecast meteorology to assimilated meteorology. Model results are compared to available satellite and ground-based observations of PM2.5 and aerosol optical depth and we attempt to quantify overall forecast skill.
Investigating the weather effects of smoke aerosols in the Unified Forecast System: A study of 2020 summer North America wildfires
Sarah Lu, JCSDA & UAlbany
Observational and numerical studies have shown human-induced climate change leads to an increasing trend of wildfire activity and severity in western boreal North America. Warmer and drier climate is favorable for the occurrence of wildfire activities, which could cause the increase of smoke aerosols.
The 2020 fire season was a record setting season for the western United States, with more than 8 million acres burned. Previous studies have projected significant increases in boreal forest fire occurrence, area burned, and fire intensity for a changing climate. In this study, we adopted the NOAA community model, the Unified Forecast System (UFS), to investigate the impact of smoke aerosols from wild fires on medium range weather forecasts. The UFS was modified to include the option to frequently update the aerosol distributions during the forecast (i.e., rapid refresh of the aerosol loading). We conducted a series of 7-day UFS forecasts, initialized from 00Z of NOAA analysis, during Aug 22nd -Sep 18th, 2020. The control UFS run considers climatological aerosol loading while the rapid refresh UFS run updates aerosol fields every 6 hour. Only direct aerosol-radiative effects are considered in both UFS runs. We will report aerosol-induced changes in UFS results, including 1) the impact of smoke aerosols on radiation, 2) the sensitivity in the thermodynamic fields, and 3) the weather effects of smoke aerosols.
Examining the regional impacts of smoke shading on smoke transport and chemistry
Adam Kochanski, San Jose State University
For this study, we combined a high-density air quality network located in Salt Lake City (SLC) with model analyses generated by a coupled fire-atmosphere model (WRF-SFIRE-Chem) to explore how wildfire smoke impacts urban air quality. This work examines two distinctly different wildfire smoke episodes in SLC where the first episode was associated with smoke that originated from a local wildland fire, while the second smoke episode was likely caused by regional wildland fires. Preliminary results indicate that WRF-SFIRE-Chem was able to skillfully simulate smoke dispersion in terms of the shape and magnitude of the smoke plume when evaluated with our high-density observation network. On average, modeled PM2.5 concentrations for SLC were 24 μg m-3 while observed concentrations averaged around 30 μg m-3. The local smoke event was dominated by small-scale mountain valley circulations, which were captured by our smoke model. For the regional case, WRF-SFIRE-Chem was able to reproduce the large-scale transport of smoke when evaluated with air quality observations across the Western U.S. Interestingly, the large-scale smoke plume exhibited sensitivity to smoke shading effects by altering the location of the highest smoke concentrations by upwards of ~200 km. Ozone concentrations was also greatly reduced in the thickest portions of the smoke plume by upwards of 10-20 ppb relative to the WRF-SFIRE-Chem simulation where smoke shading effects were turned off.
Ozone Enhancement Due to the Lake Breeze and Upwind Wildfires in The Great Lakes Basin
Tsengel Nergui, Lake Michigan Air Directors Consortium
The Great Lakes is a unique, land-locked mid-latitude geographical setting, where complex atmospheric processes take place in conjunction with local human activity, air pollutant transport, and meteorology modulated by climate variability. Ground level ozone pollution is a persistent problem in the region; several areas adjacent to the lake shores do not meet the current U.S. ozone standard. The lake-to-land breeze and transported pollutants from upwind wildfires are often associated with elevated ozone in the region. Quantifying the ground-level ozone enhancement due to the lake breeze and wildfire smokes is needed for building a strong scientific foundation to support ozone mitigation policies in the region.
We present an assessment of the ozone enhancement at monitors in the Great Lakes region during lake breeze days and wildfire-influenced days in the recent years. We applied a Classification and Regression Tree analysis on surface ozone relevant observations. We identified lake breeze days using the Visible Infrared Imaging Radiometer Suite true color imagery on the MODIS satellite and Doppler radar. Wildfire-influenced days were identified by LADCO’s exceptional event screening metrics. The surface meteorology and transport conditions associated with lake breeze or wildfire events will be discussed in the context of how inter-annual climate variability influences air quality in the Great Lakes Basin.
Diablo Wind Impacts on Turbulence Fluxes
Holly Oldroyd, University of California, Davis
Diablo winds are one of several named winds that occur when an inland trough over Canada deepens into the Intermountain West causing an inverted ridge positioned off the West Coast. This ridge drives an east northeasterly flow from the surface to mid-levels. Characterized as extremely strong, warm and dry, Diablo winds pose severe wildfire hazards and have been a driving force behind some of the most destructive fires in northern California. While these mean wind characteristics are well-known, the turbulence and land-atmosphere interactions are under-studied. We present turbulence observations from eddy-covariance stations in northern and central California. During Diablo wind events, the near-surface meteorology exhibits reduced relative humidity, reduced diurnal changes in air temperature, and elevated wind speeds compared to typical baseline conditions. Turbulence quantities exhibit strong surface shear stresses and high turbulence kinetic energy. Nighttime sensible heat fluxes are strongly negative (H < -100 Wm-2) and some positive latent heat fluxes occur suggesting nocturnal evaporation. These are likely attributable to the relatively warm, dry winds blowing over the sites. Compared to a frontal passage for which wind speeds are also elevated, the mean thermodynamic and turbulence flux signatures are different from those during Diablo events. These data provide important information for comparisons for regional-scale models used for characterizing fire danger risks.
Impacts of mineral dust events on PM2.5 and PM10 concentrations in the remote and urban regions of the U.S.
Jenny Hand, Cooperative Institute for Research in the Atmosphere, Colorado State University
Dust storms are extreme events that can have significant impacts on visibility and PM2.5 and PM10 concentrations (mass of particles with aerodynamic diameters less than 2.5 µm and 10 µm, respectively) in both urban and rural regions of the United States. Fine mineral dust, derived from PM2.5 speciated elemental concentrations, and aerosol coarse mass (CM = PM10 – PM2.5) were evaluated at rural and remote sites across the United States using data from the Interagency Monitoring of Protected Visual Environments (IMPROVE) speciated aerosol monitoring network. In addition, data were evaluated at urban sites from the Environmental Protection Agency (EPA) PM2.5 Chemical Speciation Network (CSN) and the Federal Reference Method (FRM) network. These data were used to compare the frequency of significant impacts from dust events on PM2.5 and PM10 concentrations in remote and urban regions of the United States. Quantifying the magnitude and frequency of these impacts is important for identifying local and regional dust sources, evaluating dust environmental impacts, and potentially designing mitigation strategies to reduce the influence of extreme dust events on particulate mass and visibility budgets.
Worldwide pyrocumulonimbus inventory reveals the frequency, variability, and stratospheric impact of smoke-infused storms during 2013-2021
Dave Peterson, Naval Research Laboratory
This study provides the first comprehensive inventory of all known pyrocumulonimbus (pyroCb) events observed worldwide (546 events) over the nine-year period 2013-2021. PyroCbs are a dangerous and severe type of fire weather, which present many hazards to firefighting efforts and communities in the wildland-urban interface. These unique storms also serve as a vertical transport pathway (large chimney) facilitating rapid injection of smoke into the upper troposphere and lower stratosphere (UTLS). This inventory provides insight into basic questions on inter-annual, seasonal, sub-daily, and regional variability of pyroCbs, along with potential controlling factors. Development of this inventory has included detailed analysis of the distribution and variability of pyroCb smoke injection altitudes, quantitative estimation of the aerosol mass associated with each stratospheric plume, and examination of the impact of pyroCb activity on stratospheric aerosol loading worldwide. This pyroCb inventory provides the means to address a wide range of open questions about the nature, behavior, and impact of this phenomenon. Answers to these questions are critical for advancing pyroCb prediction capabilities to aid firefighting efforts. This new multi-year inventory dataset also sets a foundation for an official Earth System Data Record that can be maintained into the future and extended back in time to identify longer-term trends in pyroCb activity and ensuing impacts on the climate system.
Recording of Presentation Presentation PDF
Anatomy of a high winter ozone episode in Colorado
Andrew Langford, NOAA Chemical Sciences Laboratory
An unusual episode with surface ozone (O3) concentrations exceeding the National Ambient Air Quality Standard (NAAQS) occurred along the Rocky Mountain foothills near Boulder and Ft. Collins, Colorado on April 17, 2020 during the COVID-19 lockdown. This high O3 event coincided with the descent of a deep stratospheric intrusion above northern Colorado and followed back-to-back upslope snowstorms that left the ground covered with snow. Lidar measurements show that little if any of the O3-rich lower stratospheric air reached the surface, but the statically stable lower stratospheric air suppressed development of the convective boundary layer, trapping NOx and VOCs from local transportation and heating sources and regional oil and natural gas (O&NG) operations near the surface to precipitate a photochemical episode similar to the winter ozone events that occur in the O&NG producing basins of northeastern Utah and southwestern Wyoming. In this paper, we use lidar and surface measurements in conjunction with the WRF-Chem and GEOS-CF models to examine the evolution of this event, and use a 0-D box model to assess the relative contributions of the different precursor sources and determine what role, if any, the COVID-19 lockdown played in this event.
Recording of Presentation Presentation PDF
Poster Presentations
Recordings of Lightning Talks
Towards an end-to-end data assimilation system for atmospheric composition with JEDI Skylab
Maryam Abdi-Oskouei, UCAR/JCSDA
Joint Effort for Data Assimilation Integration (JEDI) is a unified data assimilation (DA) framework for Earth system prediction and reanalysis. JEDI can be used for both research and operational purposes with the objective of reducing redundant work within the community and increasing the efficiency and flexibility of transition from development to operations. This presentation summarizes the recent progress in data assimilation of aerosol and trace gases using the JEDI framework in the context of the SkyLab model (GOCART and GEOS-CF).
First our generic infrastructure will be presented covering the different building blocks of the JEDI system. The presentation will cover the novel advances and efforts for aerosol DA (using VIIRS and MODIS AOD). We will use an Ensemble of Data Assimilation (EDA), along with other developments incorporated from the JEDI community. Lastly, we will show the recent developments and future directions for trace gas DA using TropOMI CO total column and NO2 tropospheric column retrievals. A novel 4D Ensemble Variational (4DEnVar) approach is being developed to constrain both concentrations and surface fluxes using satellite observations.
High-resolution WRF-Chem modeling of June 2022 ozone exceedance events in the Lake Michigan region
Jerrold Acdan, University of Wisconsin-Madison
Many counties along the coastline of Lake Michigan experience surface ozone concentrations exceeding the National Ambient Air Quality Standards set by the U.S. Environmental Protection Agency. This air quality problem affects more than 10 million people living in the states of Illinois, Indiana, Michigan, and Wisconsin and is thus an important topic of research. In this work, we utilize the Weather Research and Forecasting model coupled with Chemistry (WRF-Chem) to study the formation and transport of ozone air pollution in the Lake Michigan region. With June 2022 ozone exceedance events as case studies, we conducted sensitivity tests to investigate the impact of: (1) using the Building Environment Parameterization (BEP) urban physics option and (2) incorporating soil moisture analysis data derived from Soil Moisture Active Passive (SMAP) satellite observations on the simulation of meteorological variables (e.g., wind speed and direction, planetary boundary layer height, etc.) and air pollutant transport within the model.
A Quantile Conserving Ensemble Filtering Framework: Next Generation Nonlinear and Non-Gaussian Data Assimilation for Tracers
Jeffrey Anderson, National Center for Atmospheric Research
Ensemble Kalman filters make implicit assumptions about Gaussianity and linearity. This presentation describes novel efficient algorithms that can use arbitrary continuous priors and likelihoods for an observed variable avoiding the need for assumptions of Gaussianity. The key innovation is to select posterior ensemble members with the same quantiles with respect to the continuous posterior distribution as the prior ensemble had with respect to the prior continuous distribution. While this method leads to improvements in analysis estimates for observed variables, those advantages can be lost when using standard linear regression to update other state variables. However, doing the regression in a transformed bivariate space guarantees that the posterior ensembles for state variables have all the advantages of the observation space quantile conserving posteriors. For example, if state variables are bounded then posterior ensembles will respect those bounds. The posterior ensembles also respect other aspects of the continuous prior distributions. This avoids any implicit assumptions of linearity in the ensembles. Examples are shown for a variety of bivariate prior ensembles including bounded quantities and multimodal distributions. Results from cycling assimilation for an idealized tracer transport model demonstrate significantly improved data assimilation for distinctly non-Gaussian quantities like tracers in Earth system models.
How do we underestimate the impact of dust events on air quality
Karin Ardon-Dryer, Texas Tech University
Dust events are an important and complex constituent of the atmospheric system that can impact Earth’s climate, the environment, and human health. Most of the estimations of the impact of dust events on air quality are based on daily PM10 and PM2.5 concentrations (particulate matter with an aerodynamic diameter <10 and 2.5 μm, respectively). Many dust events (even some extreme dust storms) do not go above the EPA daily thresholds, the reason lies in the time scale of the measurements. Observation of PM during dust events which are based on daily and hourly values showed a low impact of dust events on air quality (even during some extreme dust storms). But these hourly and daily measurements underestimate the true impact of convective dust events. Observations based on a shorter timescale (10 min) reveal the true impact of short-duration (convective) dust events on air quality, leading us to speculate that the impact of these dust events is underestimated with the current (hourly basis) method. It is speculated that dust events contain mainly large particles but measurements during different dust events in Texas showed an increase of concentrations of particles <2.5 μm. Examples from several extreme dust events from Texas and Arizona will be presented.
An evaluation of lidar derived ozone curtain profiles from the TRACER-AQ campaign and WRF-Chem simulation
Claudia Bernier, University of Houston
The Houston-Galveston-Brazoria (HGB) region is susceptible to unique local emissions, transport, and meteorological factors that lead to large tropospheric ozone variations. A consistent and highly detailed variety of measurements is essential in understanding the development and behavior of tropospheric ozone in this region. The 2021 Tracking Aerosol Convection ExpeRiment – Air Quality (TRACER-AQ) campaign addressed this need by utilizing ozone lidars, sondes, off-shore boat, aircraft, and a string of additional measurements to capture a wide range of ozone cases in the HGB region for the month of September. Using the multi-dimensional ozone lidar curtain profiles, we investigate diverse vertical and temporal fine tropospheric ozone cases. The WRF-Chem model is run for the course of the campaign period at nested domains at 12, 4, and 1.33 km. Using TROPOMI satellite retrievals, we infer and test the current emissions used in the simulation. We evaluate the model’s ability in capturing the varying temporal and vertical ozone structure during two distinct ozone episodes.
Influence of meteorological conditions on PM2.5 concentrations in Ho Chi Minh city, Viet Nam: a merging measurements and WRF/CMAQ models approach
Long Bui Ta, Ho chi minh city university of Technology (Bach Khoa University)
The strict clean air action plan in Vietnam launched in 2016 aims to reduce PM2.5 pollution. However, the socio-economic development in HCMC still has to use old technologies, so the plan to reduce pollution is needs to be clarified the dependence of PM2.5 pollution on both emission factors and meteorology. In this study, the coupled WRF/CMAQ models is used to assess the dependence of PM2.5 pollution level on meteorological factors. Three years from 2018 to 2020 were considered. To calibrate and validate the WRF model, a set of measured meteorological data is used. The CMAQ model is used to simulate the distribution of PM2.5 spatiotemporal distribution. Group of six meteorological factors including wind speed (Ws), temperature, precipitation, relative humidity, surface pressure, height of the Planetary Boundary Layer (PBL) are selected for consideration. The results show that, in the period of 2018 - 2020, in the dry season, the concentration of PM2.5 in the previous hour is considered to be the main factor contributing (72%), followed by temperature (8.8%), precipitation (8.3%), surface pressure (6.8%), wind speed (3.5%). In the wet season, the concentration of PM2.5 in the previous hour is still the main factor contributing (43%), however meteorological factors in the wet season have a significant contribution higher than that in the dry season, specifically wind speed (20.3%), temperature (16.6%), precipitation (10.5%), surface pressure (6.1%).
Global sectional aerosol microphysics simulations the January 2022 Hunga Tonga Eruption
Parker Case, NASA
We have used a sectional microphysics module within the NASA GEOS Earth system model to simulate the volcanic aerosol plume following the January 2022 Hunga Tonga eruptions. While OMPS nadir mapper observations show the injection of sulfur dioxide was moderate (~0.4 Tg) [Carn et al., 2022], the MLS shows the amount of water vapor injected during the eruptions was immense (>100 Tg) [Millán et al., 2022], with early model simulations projecting the water to impact the composition of the stratosphere for up to a decade. The presence of this amount of water creates a unique natural experiment. Using the NASA GEOS Earth system model coupled to the CARMA sectional aerosol model and the GEOS-Chem tropospheric and stratospheric chemistry mechanism, we have simulated the extent of these effects, focusing on the microphysics and impacts of the sulfate aerosols resulting from the unique conditions of the Hunga Tonga plume. We evaluate our size-resolved model with observations including balloon-born particle size observations from La Réunion (21°S, 55°E) as well as spectral aerosol extinction information from the OMPS-LP satellite instrument. Our simulations are useful in showing how this injection of water and aerosol precursors are impacting the temperature, ozone chemistry, oxidizing power, and aerosol microphysical properties of the stratosphere and complement the story told by satellite, ground-based, and balloon-borne observations of the volcanic plume.
Development and Implementation of a Novel Bias Correction Technique for GFSv15-CMAQv5.3.1 Air quality Forecasting System
Xiaoyang Chen, Northeastern University
Will be presented by Yang Zhang on behalf of Xiaoyang Chen
The offline-coupled Global Forecast System with the Community Multiscale Air Quality modeling system (GFS-CMAQ) has been developed by the U.S. National Oceanic and Atmospheric Administration (NOAA) as the intermediate system of the next-generation National Air Quality Forecast Capability (NAQFC). The GFSv15-CMAQv5.3.1 system is employed by NOAA to perform air quality forecast studies for the period of Jul to Dec of 2019 over the contiguous U.S.. Evaluation of the predictions against ground-based observations indicates systematic biases for predicting ozone (O3) and PM2.5 in specific regions and seasons. In this work, a novel bias correction method is developed for the above system to reduce the systematic biases and improve its forecast skills. This method is based on integrating three techniques (Kalman filter, Kolmogorov–Zurbenko filter, and inverse distance weighted interpolation) and is applied to postprocess the predictions of O3, PM2.5, and key precursors such as NOx, SO2, CO, and isoprene. The integrated technique can meaningfully reduce the errors and absolute biases in forecasting these species. The method is then implemented in forecast runs and examined. This study demonstrates that the technique can effectively reduce forecast biases not only for predicted O3 and PM2.5, but also for their key precursor species. The integrated technique can be potentially applied to reducing systematic biases for other air quality forecasting systems.
Turbulence Time Series Analysis for Partitioned Methane Fluxes from Reservoirs
Corrin Clemons, University of California, Davis, Department of of Civil & Environmental Engineering
Global fresh-water methane emissions are historically underestimated due to their difficulty to predict and measure as they are driven by complex environmental, biogeochemical, and physical interactions in the sediment, water column, and local atmosphere. To better understand such systems, we began an ongoing study in May 2023 measuring GHG fluxes to the atmosphere using the eddy-covariance technique at Uvas Reservoir in Morgan Hill, California, managed by Santa Clara Valley Water District. Ebullition (bubbling) fluxes can contribute a significant proportion of methane releases from reservoirs in Mediterranean climates yet is sporadic and challenging to quantify. Our high-frequency measurements allowed us to partition diffusive and ebullitive fluxes through wavelet transformations that shift discrete oscillations, or wavelets, across the data set to generate wavelet coefficients. Coefficients for the scalar values of temperature, water vapor, and carbon dioxide were correlated to those for methane to evaluate the scalar transport similarity. Deviations from a linear correlation signaled heterogenous source distributions caused by ebullition. This partitioning method indicated a significant role of ebullition in total methane emissions and produced diffusive fluxes similar to those measured by point chambers. Future work will incorporate these findings with sediment and water measurements over larger timescales to understand the mechanisms driving these fluxes in the system.
Urban Air Quality Across the Globe with MUSICAv0
Louisa Emmons, NCAR/ACOM
Air quality is primarily driven by local anthropogenic emissions sources, but it can also be strongly influenced by long-range transport of pollutants and regional influences (natural emissions, chemistry, meteorology, climate). In turn, local air quality can have impacts that extend all the way to the global scale. MUSICAv0, MUlti-Scale Infrastructure for Chemistry and Aerosols Version 0, a configuration of CESM2.2(CAM-chem) with variable resolution, now has the unique capability to simultaneously simulate urban-scale air quality with high horizontal resolution and regional-to-hemispheric-to global influences and impacts of pollutants, while still using an expensive chemistry and aerosol scheme. Making use of new computer resources at NCAR, a custom variable resolution mesh, with 3 refined regions of special interest targeting the United States, Europe and southern and eastern Asia, is being used to simultaneously simulate air quality at city scales and hemispheric-scale transport of pollutants. This grid will also replicate the coverage of the three geostationary satellites that will soon provide atmospheric composition observations (GEMS, TEMPO, and Sentinel-4). Prior to that data being available, these model simulations will help prepare for analysis of the constellation observations; and in the near future retrievals from GEMS over East Asia and TEMPO over the U.S. will be used for model evaluation.
On The Role of Simplified Models in Understanding Background Tropospheric Ozone and its Contributions to Maximum Surface Concentrations Across the Continental US
Ian Faloona, UC Davis Air Quality Research Center
Coauthors: D.D. Parrish, R.G. Derwent, and C.A. Mims
Despite largely successful regulatory control efforts, several areas of California still exceed the ozone National Ambient Air Quality Standard (NAAQS) of 70 ppb, and this threshold is continually lowered as the health impacts of exposure become better understood. As precursor emissions continue to decrease, ozone levels appear to be reaching a plateau, and consequently, the nature and secular trend of hemispheric background ozone is becoming more important as its proportional contribution to exceedances of the NAAQS are on the rise. Moreover, State Implementation Plan (SIP) modeling of the trends of ozone across California have erroneously predicted attainment of the NAAQS which, in fact, have never been observed. While models of reduced complexity are routinely used in geophysical fluid dynamics to study complex phenomena, the use of analogous models in the atmospheric chemistry community is anathema. We present here a conceptual model of the midlatitude background tropospheric ozone field and outline how it impacts surface concentrations across the continental US depending on geography and boundary layer dynamics. We further show that after the mid-2000's background ozone has been gradually decreasing; however, we also call attention to several recent studies indicating a rise in the ozone flux from the stratosphere due to an accelerated Brewer-Dobson circulation and weakening stability caused by rising levels of greenhouse gases.
Combining High Spatial Resolution Fire Information with Daily Fire Activity to Improve a Fire Emissions Estimates
Sam D. Faulstich, University of Utah, Department of Chemical Engineering
Modeling human exposure to wildfire smoke is a crucial component of estimating the health impacts of wildfire smoke. In order to estimate smoke exposure, the amount of PM2.5 emitted by each fire is required. Because fire emissions cannot be directly measured, a model called a fire emissions inventory (FEI) is required to estimate the emissions information. FEIs face uncertainties because fire behavior is complex and difficult to model. These uncertainties are further propagated through atmospheric dispersion models and health studies that use FEIs.
Satellite remote sensing is necessary in FEIs due to the large amount of area that needs to be surveilled on a daily basis. However, satellite remote sensing misses fire activity due to cloud cover and sensing limits, leading to underestimated fire activity. This work combines two sources of satellite remote sensing information to provide fire emissions estimates that are high resolution both spatially (30 m resolution) and temporally (daily resolution), reducing errors caused by missing small fires. A linear regression is applied in order to account for missing fire activity likely due to cloud cover. Initial results show that for 2013, approximately 25% more fire activity days are included when using the cloud cover interpolation.
Evaluation of the HYSPLIT-WRF-Chem framework to simulate volatile phenols under wildfire conditions. Case study: two wildfire smoke events at a central Washington State winery.
Ana Carla Fernandez Valdes, Washington State University
The presence of volatile phenol (VP) in the atmosphere can negatively influence human health and the environment. VPs can also accumulate in grapes causing detrimental effects on the wine industry. The primary source of high concentrations of VPs in wine comes from smoke contamination from wildfires, commonly known as smoke taint. These compounds can impart smoky, ashy flavors to wines which affect their quality and marketability. During the past decade, western US wineries have been impacted by this phenomenon, especially during the 2020 season. In this study, we investigate the capabilities of an air quality modeling framework to provide information on two wildfire events in a winery in central WA. Several chemical mechanisms within the WRF-Chem model were used to investigate their capabilities to simulate the behavior of VP in the troposphere, including their sources, chemical reactions, transport, and fate during both smoke-tainted and non-smoke-tainted conditions. Additionally, we performed back trajectories simulations using the HYSPLIT model to identify the sources, pathways, and travel time of the air parcels that arrive at the wineries. Combining the outputs of the chemical transport model and the results from a back trajectory analysis we were able to characterize the photochemical aging of smoke plumes and identify the fate of VP at both the wineries locations and through the trajectories.
Assessment of modern climate change on the territory of Central Asia.
Sh. Khabibullaev Forukh Boltabaev, METEOINFOCOM
Modeling of time series of air temperatures and precipitation was carried out for 75 meteorological stations of the Republic of Uzbekistan from 1966 to the present. It was revealed that the greatest manifestation of climate change affects the temperature in July and its stepwise growth has been observed since 1973. At meteorological stations near the Aral Sea, there was a second increase in the average temperature in 2007, associated with the desertification of the territory. The increase in January temperature is insignificant and is observed at several individual stations, as well as the manifestation of modern climate changes in the precipitation series is practically not observed due to their high natural variability.
Predicting major pollutant concentrations and linkages to emissions, meteorology and policy implications in Beijing, China using machine learning methods
Shreya Guha, George Mason University
Air pollution is a major contributor to adverse health outcomes, with particulate matter of aerodynamic diameter less than 2.5um(PM2.5) and tropospheric or surface ozone being the dominant sources for premature mortality globally. The concentrations of these pollutants are highly dependent on both source emissions and meteorological factors. In 2013, China launched the Air Pollution Prevention and Control Action Plan to cut the PM2.5 source emissions, which helped in reducing its concentrations in Beijing. However, the city also experienced an increase in ozone concentration since 2013. This study aims to evaluate and quantify the effects of daily meteorology on these heterogeneous changes in ambient air pollutant concentrations in Beijing from 2011 to 2020. For this, other than relying on a specific dataset, we have assessed and combined several datasets ranging from ground observations to model reanalysis products. This study employs detrending technique in combination with the application of an array of models with increasing levels of intelligence to develop the best possible model for separating out meteorological influences. Thus, we can successfully identify the trend for the anthropological contributions to the changing air quality levels in response to the recent policy implementations in Beijing. Having this information can help in extending the use of this model across various other locations and building more effective environmental policies in the future.
Harnessing our Air Quality Modeling & Observational Capabilities to Establish Key Factors Influencing Ozone Levels in Arizona
Yafang Guo, The University of Arizona
Currently we do not understand how the unique southwest semi-arid environment and potential sources of main O3 precursors in Arizona (NOx, AVOCs, BVOCs) influence O3 abundance across the state so it is not clear which types of controls can be put in place. Because of the unique southwest natural environment including weather, climate, and desert plants in Arizona, it is also important to understand how the extreme heat, low moisture, and all year desert shrubs contribute to the O3 production and hence better control the O3 exceedance and air quality forecast. The objectives of this work are: 1) conduct O3 simulations for the recent decade and evaluate the hourly-to-decadal variations of simulated O3 and associated compounds with existing USEPA AQS datasets; 2) assess how the urban area shifts between NOX-limited and VOC-limited regime over the year through a series of model experiments as weather and desert ecosystem influences O3; 3) quantify the relative contributions of the following: transport of O3 precursors from nearby states (e.g., California, northwest Mexico) and fires. We use a “tagging” approach within the WRF-Chem model that attributes elevated O3 concentration in Arizona to nitrogen oxide (NOx ) emissions from within and outside the state during June month from year 2017 to 2021. Model is configured with two one-way nested domains with 9- and 3-km grid spacing, with the outer domain encompassing the western US and inner domain covering entire state of Arizona.
Investigating the role of nocturnal heterogeneous chemistry on daytime air quality: a comparison of two modeling schemes
Alicia Hoffman, University of Wisconsin - Madison
Nitrogen oxides (NOx ≡ NO + NO2) have a major effect on air quality in the United States because they have direct human health impacts and play a central role in the production of secondary pollutants like ozone and particle pollution. Nighttime heterogeneous chemistry – the chemistry occurring between particles and gases – regulates the reservoirs and sinks of NOx, leading to large impacts on daytime air quality. However, the simplified nocturnal heterogeneous NOx chemistry in air quality models is not consistent with field measurements and results in poor prediction of NOx reservoir species concentrations such as N2O5 and ClNO2. To assess the impact of nocturnal heterogeneous chemistry on daytime NO2 concentrations, we compared two different chemistry schemes in the Community Multiscale Air Quality (CMAQ) model. The two schemes we assessed were the default setting in CMAQ and an updated scheme that had a new N2O5 uptake parameterization and a new ClNO2 yield parameterization. This new chemistry incorporated the effects of organic coatings on particles to reduce N2O5 uptake and the competitive effects of sulfate in particles to reduce ClNO2 yield. These heterogeneous chemistry mechanisms have large impacts on the particle nitrate composition and early-morning NO2 concentrations, which impact human health, environmental quality, and the climate.
Meteorological impacts on the spatial distribution of air pollution in Salt Lake City
Heather Holmes, University of Utah
Meteorology plays a significant role in poor air quality during winter in mountainous regions. In mountain valley basins, local stagnation events lead to pollutants being trapped in cold dense air, a cold air pool (CAP). One location that experiences CAPs is the Wasatch Front in northern Utah, home to more than 2.5 million people. Salt Lake City (SLC) is the largest city this region. There are multiple sources of air pollution emissions in SLC: motor vehicles, aircraft, industrial, and dust from the Great Salt Lake. While the emissions do not change during CAPs, the physics and chemistry of the atmosphere changes, resulting in different PM2.5 composition. The spatial distribution of regulatory air quality monitors is limited, e.g., three speciated PM2.5 monitors in the Wasatch Front with one in SLC. More sensors are available for PM2.5, but not enough to quantify the intra-urban spatial variations. The spatial coverage can be improved by using data form the AQ&U sensor network, with more than 200 PM2.5 sensors in SLC. Another limitation in studying wintertime air pollution is quantifying the meteorological drivers contributing to the poor air quality. This presentation will show results that illustrate the meteorological impacts on the spatial distribution of pollutants and the composition of PM2.5 during CAPs in SLC. We will present a new method to identify CAPs and the CAP influence on the spatial PM2.5 concentrations will be presented using results from AQ&U.
Constraints on anthropogenic NOx, CO, and VOCs emissions over the US by assimilating multi-constituent TROPOMI satellite measurements
Chia-Hua Hsu, Department of Mechanical Engineering, University of Colorado, Boulder
NOx, CO, and VOCs are air pollutants and precursors to PM2.5 and O3 air pollution. The diverse and dynamically evolving natural and anthropogenic sources of these emissions pose a challenge for emissions estimation. This work aims to simultaneously optimize NOx, CO, and VOCs anthropogenic emissions by assimilating multi-constituent (e.g., NO2, CO, CH2O, and O3) TROPOMI observations and studying the impact of emissions inversion on O3 simulation/forecast. In this research, WRF-Chem/DART, a regional ensemble chemical weather forecast and data assimilation system, is used to conduct the emissions inversion on a daily basis. The potential study periods are focusing either on April 2020, which is during the COVID-19 lockdown, or the AEROMMA field campaign (summer 2023). We will first constrain NOx and CO emissions by assimilating TROPOMI NO2 and CO measurements, respectively. For inverse modeling of VOCs emissions, we will jointly assimilate TROPOMI CH2O and O3 data and study the capability of these observations to constrain various VOCs emissions species. We will also investigate the impact of conducting emission inversion in a non-Gaussian framework (e.g., log-normal, and non-Gaussian filter), which may improve the performance of emissions estimates because the distribution of trace gas concentrations and emissions tends to be non-Gaussian.
Towards Improved Understanding of Wildfire Smoke Plume Height Estimation in Western U.S. Using Multisource Satellite Observations
Jingting Huang, University of Utah
As wildfires intensify and fire seasons lengthen in western US regions, accurate models that predict smoke density and location are becoming increasingly critical. Smoke plume height (SPH) is the key to understanding wildfire intensity and aerosol sources in climate and air quality models. Global-scale satellite data with improved spatiotemporal resolution can aid in estimating wildfire emissions and SPH.
This study evaluated different satellite remote sensing techniques used to retrieve wildfire SPH using aircraft data from the Wyoming Cloud Lidar (WCL) during the 2018 BB-FLUX field campaign. Two definitions— “plume top” and “extinction-weighted mean height” —were used to derive representative heights of wildfire smoke plumes, based on aerosol extinction coefficient vertical distribution from the WCL measurements. Smoke plume height products retrieved from multiple satellite sources were intercompared and analyzed with these two definitions for SPH.
Results indicate that plume height products from MISR can capture the topmost aerosol layer, whereas TROPOMI tends to represent the smoke aerosol optical centroid. Besides, the MODIS/MAIAC algorithm-derived injection heights exhibit high uncertainties, and the VIIRS/ASHE algorithm-derived aerosol layer heights are biased high due to their coarse spatial resolution. These findings are expected to inform future satellite remote sensing missions and Earth observation data selection for mapping smoke aerosol vertical distribution.
UAV Measurements in a Heavily Burdened Air Basin to Understand Meteorological and Emissions Uncertainties in CMAQ
Cesunica Ivey, University of California, Berkeley
Air quality non-attainment is a well-known challenge in the South Coast Air Basin of southern California. The region suffers due to the compounding effects of onshore winds, opposing mountain ranges, abundant anthropogenic emissions, and persistent sunlight to catalyze the formation of secondary pollutants, namely ozone and secondary particulate matter (PM). We explore concentrations of ozone and PM2.5 at the surface and up to 500 meters using an unmanned aerial vehicle in Riverside, CA from August to November 2020. Resulting from this effort were 376 vertical profiles of ozone and PM2.5. The Community Multiscale Air Quality (CMAQ) model was run to generate comparison ozone and PM2.5 concentrations and to better understand model emissions and meteorological discrepancies. Several simulations were run to determine model bias after modifications to eddy diffusivity, planetary boundary layer height, NOX emissions, and VOC emissions. Diurnal dependencies were observed for model biases related to both meteorology and emissions. Specifically, our evaluation revealed model inconsistencies due to underestimations of modeled NOx and misrepresentation of PBL evolution. We note that these model errors are associated with inland southern California, and we conclude that UAV field experiments are valuable for improvements in region-specific model performance.
Source Apportionment and Integrated Process Analyses to Probe CMAQ Model Biases during Wintertime PCAP Events
Cesunica Ivey, University of California, Berkeley
Mountain cities in the western U.S. are oftentimes impacted by extreme pollution events brought on by stagnant high-pressure systems in the winter, coupled with temperature inversions and limited dilution. Periods of stagnation lasting longer than 36 hours are known as persistent cold air pool (PCAP) events and can be associated with ambient fine particulate matter concentrations well above the 24-hour PM2.5 NAAQS of 35 µg/m3. Here we investigate concentrations, source impacts, and model process contributions within CMAQ for PM2.5 in winter 2016 for three cities: Fresno, CA, Reno, NV, and Salt Lake City, UT. Several PCAPs were identified and were associated with dips in modeled relative humidity. PCAP periods were also characterized by underestimated secondary PM2.5 in all locations. Source-specific underestimations were also explored using the decoupled direct method paired with bias corrections, and sources spanned 20 unique, fuel- and activity-based categories. We also explored the contribution of biases to specific modeled processes using the integrated process analysis tool in CMAQ. Preliminary results suggest that aerosol processes, relative humidity, and the cloud microphysics option are the primary drivers for model bias during PCAP events.
NASA GEOS Composition Forecast System, GEOS-CF: Overview, Applications, and Future Directions
K. Emma Knowland, 1) Morgan State University/GESTAR-II, Baltimore, MD; 2) NASA GSFC, Global Modeling and Assimilation Office, Greenbelt, MD
NASA's Global Modeling and Assimilation Office (GMAO) produces high-resolution analysis and forecasts for weather, aerosols, and air quality. Since 2019, the NASA Global Earth Observing System (GEOS) model provides global near-real-time historical estimates and daily 5-day forecasts of atmospheric composition to the public at unprecedented horizontal resolution of 0.25 degrees (~25 km) from the surface up to 80 km. This composition forecast system (“GEOS-CF”) combines the operational GEOS weather forecasting model with the state-of-the-science GEOS-Chem chemistry module to deliver detailed analysis of a wide range of air pollutants, including the policy-relevant species such as ozone, nitrogen oxides, and fine particulate matter (PM2.5).
The GEOS-CF is a tool for scientists and the public health community. This presentation will cover 1) an overview of the GEOS-CF modeling framework and data/visualization access, 2) examples of current and future applications to support NASA missions (e.g., a priori for trace gas retrievals by TEMPO) and stakeholders including US EPA, UNEP and cities in the Global South, and 3) research and development activities as the GEOS-CF system continues to evolve to include multi-constituent data assimilation, down-scaling methods to urban-scale, and data access on Google Earth Engine, and other platforms to integrate our state-of-the-science air quality information onto platforms used by stakeholders, air quality managers, and the public.
Broadening Systematic Reanalysis Intercomparisons in SPARC-Reanalysis Intercomparison Project Phase 2 (S-RIP2): Chemical Reanalyses & Air Quality, Tropospheric Circulation, Extreme Events, and More
K. Emma Knowland, 1) Morgan State University/GESTAR-II, Baltimore, MD; 2) NASA GSFC, Global Modeling and Assimilation Office, Greenbelt, MD
Presenting on behalf of Gloria L. Manney
Katabatic Flow Turbulence Modeling
Yicheng Li, UC Davis, Civil and Environmental Engineering
Katabatic downslope winds are generated by negative buoyancy through the cooling of air near inclined surfaces, especially over mountains and glaciers. This study focuses on RANS (Reynold averaged Navier-Stokes) modeling of these flows. Katabatic winds transport pollutants and CO2 downhill and enhance turbulent mixing. Understanding and predicting their impacts is difficult due to complex nonlinear dynamics, and challenges in measuring over sloping terrain. We use a modified 1-D Prandtl (1942) model to simulate katabatic flow. Our study indicates that a first-order turbulence closure model in the simulations diverges from the observations, while second-order closure models better simulate the katabatic flow structure. However, we found results from second-order closures to be particularly sensitive to the wall model formulation, which provide turbulence fluxes at the grid cell adjacent to the surface in numerical weather predictions and have been shown through observations to require modification for katabatic flows. Therefore, we implement a new data-driven wall model based on Hang (2021), which is based on a 1-D RANS model for an inclined surface based on the buoyancy-modified k-epsilon equations. The capabilities of the model have been assessed against observations. We finally highlight additional modeling challenges and propose strategies for future model improvement.
The GFDL Variable-Resolution Global Chemistry-Climate Model for Research at the Nexus of US Climate and Air Quality Extremes
Meiyun Lin, NOAA Geophysical Fluid Dynamics Laboratory
We present a 33-year AMIP simulation (1988-2020) of a new GFDL variable-resolution global chemistry-climate model (AM4VR) designed for research at the nexus of US climate and air quality extremes. With a horizontal resolution of 13 km over the continental US, AM4VR shows vast improvements upon AM4.1 at uniform 100 km resolution in representing: US precipitation seasonal cycles and daily distributions, notably reducing the central US dry and warm bias; pan-US drought, linked to model fidelity of the ENSO teleconnection; and western US snowpack, with implications for wildfire risk. AM4VR also provides improvements over AM4.1 in the process-level representations of BVOC emissions, interactive dust emissions, and interactive tracer dry deposition coupled to hydroclimate and vegetation state. We highlight the skill of AM4VR in simulating summer ozone and winter haze dominated by ammonium aerosols in California’s Central Valley, with implications for food production and public health, and the impact of drought on southwest US dust and eastern US ozone extremes via vegetation feedbacks, with implications for seasonal air quality forecasts. AM4VR captures the observed sensitivities of ozone air pollution extremes to temperature, largest in the Northeast Urban Corridor, coastal counties around Lake Michigan, and other populated areas. AM4VR offers a novel opportunity to study global dimensions to US air quality, especially the role of Earth system feedbacks in a changing climate.
Spatiotemporal Gap-Filling of NASA Satellite-Derived-AOD in North America Using The UNet 3+ Machine Learning Architecture
Marcela Loria Salazar, School of Meteorology, University of Oklahoma
Wildfire emissions forecasting is needed to provide real-time alerts and forecasts for wildfire smoke. Due to the unpredictable and chaotic nature of fire ignition and behavior, it is challenging to forecast real-time wildfire emissions and their associated impacts on air quality. Multiple smoke models have been developed using satellite-derived aerosol optical depth (AOD) because of the improved spatial coverage. However, satellite-retrieved AOD datasets suffer from large portions of missing data, usually due to cloud cover. Consequently, including AOD as a predictor for particulate matter can be challenging for models that cannot inherently deal with missing values. We created a model based on the UNet 3+ architecture to fill in these missing values based on available AOD, meteorological, and land-used datasets. Training, validation, and testing datasets were created using NASA MODIS and VIIRS Deep Blue (DB) AOD retrievals, MERRA-2 AOD, NAM reanalysis model for meteorological land-use variables, NOAA HMS, and NASA FRP for fire emissions. Additional evaluations were performed using ground-based NASA AERONET AOD observations. This study will primarily focus on the fire seasons from (2012-2022) in the continental U.S. Preliminary results show promising results; the model achieved a correlation R~0.72, root mean square error RMSE~0.14, and normalized mean bias NMB~0.13 between collocated estimated AOD values and VIIRS AOD retrievals over non-winter months (April-November).
Investigating Impacts of Local Circulation on Coastal Ozone Problem in the New York Metropolitan Area: A modeling and observational study
Sarah Lu, JCSDA & UAlbany
Elevated surface O3 levels are often detected during hot summer days in the New York metropolitan area, due to the rich sources of local anthropogenic and natural ozone precursor emissions. Moreover, surface O3 in this region exhibits extensive horizontal and vertical gradients and distinctive diurnal cycles. This study examines the spatial and temporal O3 characteristics under different cluster-based local circulation scenarios during summertime in the pre-COVID era of 2017-2019, utilizing observations from various surface networks, New York State Mesonet (NYSM) Profilers, and 2018 Long Island Sound Tropospheric Ozone Study (LISTOS), as well as composites from the reanalysis fields and National Emission Inventory. The most polluted days are closely associated with classic sea breeze days with weak large-scale flow. When sea breeze development in the New York Bight is delayed, and its penetration into the NYC and shores of western Long Island Sound is intercepted by the dominant westerlies, daily 8-hr maximum average ozone (DMA8) in the hot spots of NYC and south shore of CT would drop more than 10 ppb under comparable temperature levels. The probability of DMA8 exceeding 70 ppb is also dramatically decreased. Furthermore, meteorological characteristics, such as sea breeze onset time and strength, most critical to ozone exceedances and high peaks are identified and analyzed for future improvement in coastal ozone simulation and prediction.
Data fusion with uncertainty quantification for sub-city-scale air quality assessment and forecasting
Carl Malings, Morgan State University and Global Modeling & Assimilation Office
Many information sources can support air quality assessment and forecasting, including atmospheric chemistry model outputs, satellite retrievals of column chemical and aerosol constituents, and surface-based air quality monitoring data from both regulatory and low-cost instruments. Systematic integration of these data sources provides a major opportunity to improve understanding and management of air quality, but also presents technical barriers, especially in resource- and data-constrained settings in the Global South. This presentation describes a data fusion system, currently under development using the Google Earth Engine platform, which aims to integrate the information sources listed above to support comprehensive sub-city-scale assessment and management of air quality. Furthermore, the data fusion framework includes provisions for the quantification of uncertainties in the resulting fused estimates based on the variability of and among the input data sources. These capabilities will allow air quality managers to better understand their local air quality situation, including relative confidence in the fused estimates for different constituents, locations, and times, leading to better informed air quality management decisions. This presentation covers the underlying methodology of the data fusion and uncertainty quantification approaches, provides an update on the status of its implementation, and presents early qualitative and quantitative results.
Investigating surface ozone sensitivity to HCHO/NO2 ratios over Arizona using the Multi-Scale Infrastructure for Chemistry and Aerosols (MUSICA) model
Seyed Mohammad Amin Mirrezaei, Department of Hydrology and Atmospheric Sciences, University of Arizona
Ozone pollution in semi-arid environments such as Arizona, where the primary precursors including NOx, anthropogenic, and biogenic VOCs varies with time and space, requires determining the relative contributions of these components to ozone production. Due to the lack of spatial distribution of surface measurements and the temporal limitation of satellite retrievals, multiscale air quality modeling can be a great tool for covering the deficiencies of satellite and surface measurements as well as addressing the discrepancies between their measurements. Here, the Multi-Scale Infrastructure for Chemistry and Aerosols Version 0 (MUSICA-v0), a global chemistry-climate model with regional refinement capability that provides down to a few kilometers’ resolution, is evaluated, and used to gain a better understanding of how horizontal resolution and chemical complexity can better represent the diurnal changes of NOx and VOC limited regimes. The MUSICA-v0 simulations with ∼14 km horizontal resolution were evaluated with tropospheric Monitoring Instrument (TROPOMI) HCHO/NO2 column ratios and surface HCHO/NO2 ratios as well as ozone concentrations compared with a Weather Research and Forecasting (WRF) model coupled with Chemistry (WRF-Chem) simulation for July and August 2019-2020. The preliminary results indicate that the performance of MUSICA is comparable to that of WRF-Chem, and it can be used for regional studies while considering all earth system components on a global scale.
WRF-Chem/DART: A Regional Ensemble Atmospheric Composition Forecast/Assimilation/Emissions Estimation System - Recent Developments and Applications
Arthur Mizzi, NASA Ames Research Center, NOAA Chemical Systems Laboratory, University of Colorado at Boulder Mechanical Engineering
WRF-Chem/DART is a state-of-the-science regional atmospheric composition (AC) forecast/assimilation/emissions estimation system based on the ensemble adjustment Kalman filter that uses the state augmentation method for constraining emissions. It has/is being used by researchers throughout North America, Asia, and Western Europe. WRF-Chem/DART’s continued development and application has been supported by NASA, NOAA, NCAR, and the University of Colorado at Boulder. This poster will provide an introduction to WRF-Chem/DART and highlight its recent development/applications which include:
- Assimilation of (i) OMI ozone (O3), nitrogen dioxide (NO2), and sulfur dioxide (SO2); (ii) TROPOMI carbon monoxide (CO), O3, NO2, and SO2; and proxy (iii) TEMPO O3 and NO2 total/partial column and/or profile retrievals (completed).
- Assimilation of (i) OMI formaldehyde (HCHO), (ii) TROPOMI HCHO and methane (CH4); (iii) TES CO, O3, ammonia (NH3), and CH4; (iv) CrIS CO, O3, NH3, CH4, and peroxyacetyl nitrate PAN; (v) GOME2-a NO2; SCIAMACHY NO2; and MLS O3 and nitric acid (HNO3) total/partial column and/or profile retrievals (in progress).
- Spatial and temporal interpolation of global model analyses/forecasts for use as upper boundary conditions for assimilation of retrievals whose vertical weighting functions have an upper boundary that is above the regional model’s upper boundary.
- Applications for COVID OSSE, FIREX-AQ Williams Flats OSSE, TRACER-I, and AC forecasting for central Mexico.
Efficient Joint Assimilation of Ozone Retrievals with Nitrogen Dioxide Emissions Estimation in Regional Air Quality Forecast Models
Arthur Mizzi, NASA Ames Research Center, NOAA Chemical Systems Laboratory, University of Colorado at Boulder Mechanical Engineering
Efficient assimilation of retrieval profiles (including O3 profiles) is necessary for comprehensive atmospheric composition forecasting. Typically, O3 (as well as other constituent) retrievals are not assimilated in regional models because the upper boundaries of the vertical weighting function matrixes (averaging kernels or scattering weights) extend beyond the upper boundary of the regional models. Additionally, the large retrieval data volumes associated with geostationary air quality satellites makes efficient assimilation of retrieval profiles increasingly important.
We combine a simple solution to assimilate of O3 retrieval profiles with the ‘compact phase space retrieval’ (CPSR) algorithm of Mizzi et al. (2016; 2018) to jointly assimilate O3 retrievals profiles from OMI, TES, MLS, CrIS (actual retrievals), and TEMPO (proxy retrievals) in WRF-Chem/DART. To solve the O3 upper boundary problem, we use global model simulations to provide spatiotemporal-dependent upper boundary conditions on O3 (or other atmospheric constituents as required) in the WRF-Chem. To solve the geostationary observation data volume issue, we assimilate CPSRs to obtain computation savings ranging between 70% and 85% depending on the ratio of the rank to the dimension of the applicable vertical weighting matrix. We will present results from the joint assimilation of O3 retrieval profiles using the: (i) conventional and (ii) CPSR approaches with and without constraining the O3–related emissions.
Joint Assimilation of CO, O3, NO2, SO2, PM, AOD, NH4, PAN, and HNO3 in Support of the Tropospheric Regional Atmospheric Composition and Emissions Reanalysis (2005 - 2024) (TRACER-I)
Aish Raman, NASA Ames Research Center, University of Arizona
NASA Ames Research Center is collaborating with the NOAA Chemical Systems Laboratory (NOAA/CSL), the NASA Jet Propulsion Laboratory (JPL), the NASA Goddard Modeling and Assimilation Office, and the National Center for Atmospheric Research to prepare a 20-year Tropospheric Regional Atmospheric Composition and Emissions Reanalysis (2005 – 2024) (TRACER-I) for the continental United States during the summer ozone (O3) and wildfire seasons (April to October). TRACER-I will be a regional complement to JPL’s global Tropospheric Chemistry Reanalyses II and III. We will use WRF-Chem/DART with NOAA/CSL’s WRF-Chem setup at 12 km x 12 km horizontal resolution, 51 vertical levels, and 30 ensemble members. We will assimilate: (i) conventional meteorological observations; (ii) EPA’s Air Quality System in situ measurements of carbon monoxide (CO), O3, nitrogen dioxide (NO2), sulfur dioxide (SO2), particulate matter (PM) with diameters less than 10 µm (PM10), and PM with diameters less than 2.5 µm (PM2.5); and (iii) MOPITT, MODIS, OMI, TROPOMI, GOME-2a, MLS, TES, SCIAMACHY, CrIS, and TEMPO total/partial column and/or profile retrievals of CO, O3, NO2, SO2, aerosol optical depth (AOD), formaldehyde (HCHO), ammonia (NH4), peroxyacetyl nitrate (PAN), and/or nitric acid (HNO3) with 3-hr cycling. We will present an overview of this project, its status, and available results (likely the analysis of sensitivity experiment results from the assimilation/emissions estimation system).
HiRes-X: Forecasting Air Quality and Health Impacts of Prescribed Fires in Southeastern U.S.
M. Talat Odman, Georgia Institute of Technology
Prescribed fire is the leading source of PM2.5 emissions in southeastern United States (US). The use of prescribed burning has economical and ecosystem-related benefits but must be weighed and managed with respect to air quality concerns and potential health and welfare impacts . We have developed the HiRes-X modeling system to provide forecasts of potential prescribed fires and their impact on air quality and human health in southeastern US. Since 2019, we have been disseminating these forecasts daily through the Southern Integrated Prescribed Fire Information System (SIPFIS). The current 48-hour lead time forecasts of PM2.5 and O3 levels and prescribed fire contributions assist the Georgia Department of Natural Resources for official forecasts of air quality for public health protection, and the Georgia Forestry Commission for permitting of prescribed burning. We will describe the components of the HiRes-X modeling system in detail and report on its past performance. We will show examples of how the HiRes-X forecasts and SIPFIS can be used for cohesive prescribed fire, air quality and health management. We will also report our efforts to further improve the HiRes-X’s capability to better predict smoke plumes. We will evaluate model predictions by comparing them to PM2.5 and O3 measurements from prescribed burns conducted at military bases in southeastern US as part of an ongoing Strategic Environmental Research and Development Program (SERDP) fire science initiative.
Observational Assessment of Aerosol Impacts on Updraft Speed in Deep Convection
Hallie Pimperl, UC Davis
Aerosols influence many cloud aspects, such as cloud development and convective dynamics, through their role as cloud condensation nuclei. Previously, modeling studies have shown evidence of higher aerosol concentrations leading to aerosol-induced invigoration of deep convective storms. (In this study, we define invigoration as an increase in cloud updraft speed.) This study uses GOES16 geostationary satellite data to track >100 isolated, deep convection over the Southern Great Plains region in Oklahoma. Updraft speeds are not
measured directly, but they are assumed to be proportional to the cloud top rise rate. The cloud top rise rates have been found to show a positive correlation with some environmental factors, such as the most unstable CAPE, as expected. After controlling for the meteorology, the rise rates are cross-referenced with the daily aerosol loadings from the ARM SGP site to determine whether or not an aerosol effect on the cloud top rise rates can be detected from the environmental controls. While the results are still preliminary, it appears unlikely that we can find a robust relationship between aerosol concentration and updraft speed.
Impacts of climate change on wildfire PM2.5 and the human health burdens in the US
Minghao Qiu, Stanford University
Wildfire and associated smoke exposure have increased dramatically during the last two decades in the US, reversing the multi-decadal improvements in fine particulate matters (PM2.5). Wildfire activity is projected to accelerate under future climate, but our understanding of the magnitude and distribution of the potential resulting impacts on human health remains highly incomplete. Here, we utilize satellite-derived daily smoke PM2.5 at 10km resolution from 2006-2020 over the continental US to project the smoke PM2.5 and associated health burdens under future climate. To do this, we first build a machine learning model to predict monthly wildfire emissions with climatic variables over the entire North America. Then for each 10km location, we establish a causal relationship between the monthly smoke PM2.5 in that location and fire emissions from potential source regions, accounting for variation in the wind directions. Combining with future climate projections, we estimate the monthly smoke PM2.5 under different future climate scenarios for each 10km location over the continental US. Mapping the projected changes to the census tract level and combining these changes with existing smoke-health concentration-response functions, we quantify the health burden due to changes in smoke exposure under future climate, including mortality and hospitalizations. We further quantify the distributions of these health burdens across different social and demographic groups.
Trace gas atmospheric rivers: remote drivers of air pollutants
Mukesh Rai, Jet Propulsion Laboratory, California Institute of Technology
Identifying key atmospheric transport events is essential to providing improved insights into the relative contributions of remote and local sources to local air quality across the globe, which in turn informs environmental policymaking that benefits air quality and climate. The concept of atmospheric rivers (ARs) has been successfully used to demonstrate key transport events for determining global patterns of water vapour and aerosols. Extending the AR concept, we propose a new AR framework, Trace Gas Atmospheric River (TGAR), to study key long-range transport events by using global trace gas data obtained from JPL chemical data assimilation system that ingests various satellite observations. To that end, we determine the global distribution, seasonal variations, and long-term trends of the TGAR patterns and the relative contribution of remote air pollutants over major megacities in the world. The results obtained for various air pollutants and their precursors with different source patterns and chemical lifetimes, such as ozone, carbon monoxide, and PAN, are evaluated and validated against independent in-situ surface observations and satellite retrievals from NASA’s TES and AIRS/OMI, and NOAA’s CrIS developed by JPL’s TROPESS project. This study will provide insights into the extreme events of pollution transport in terms of TGARs and is expected to provide a useful framework for better characterizing air quality drivers and informing chemical transport model improvements.
An evaluation of Model II Regression techniques for the intercomparison of two instrumental methods for a national air quality monitoring network
Colleen Marciel Rosales, OpenAQ / UC Davis
Most comparisons of two instrumental techniques use ordinary least squares (OLS) regression—simple, but often incorrect. Assumptions of Model I regression techniques, such as OLS, do not completely apply to techniques that both have uncertainties associated with them, since for OLS to be valid, the independent variable “x” should cause or determine the dependent variable “y”. On the other hand, Model II regression techniques, such as major axis (MA) and standard major axis (SMA) regressions, do not require this assumption, such that “x” and “y” are interchangeable, i.e., one variable does not determine the other. Model II techniques also give the chance to account for errors in both variables, making it a suitable comparison metric for instrumental methods. In this presentation, different Model II regression techniques as well as other statistical comparison metrics are explored and compared side-by-side to OLS as applied to atmospheric instrumental techniques for the elemental characterization of particulate matter collected from an ambient monitoring network.
Development of PM2.5 transport: Modeling the spatial distribution of Camp Fire from California to New York
Xiaorong Shan, George Mason University
The November 2018 Camp Fire in northern California released abundant aerosols into the atmosphere and is one of the costliest disasters in the world for insurers with insured losses totaling $12.5 billion. The event degraded air quality across the United States, with elevated PM2.5 concentrations observed across the country during this period. It is unclear, however, the extent that elevated air pollution concentrations attributable to distant wildfire emissions impacted human health. Modeled wildfire source impacts are highly dependent on the models used and their inputs, including wildfire emissions, which can be highly uncertain. Here we focus on PM2.5 exposures during the Camp Fire period (from Nov. 08.2018 to Dec. 02.2018) in New York state. To estimate exposure, we use the average values of four satellite-based fire emission data sets (FEER, FLAMBE, GBBEPx, and GFAS). Then, we employ HyADS, the HYSPLIT average dispersion model, which combines the HYSPLIT trajectory dispersion with emissions to simulate the PM2.5 daily exposure. We evaluate our results using PM2.5 observations at EPA monitors, which capture total daily variability but are limited in their ability to differentiate PM2.5 from fires. The highest correlation (R) between the HyADS and local monitors is 0.54 using the most detailed emissions data. In continuing work, we plan to employ source apportionment at EPA CSN cites to identify the portion of the observed PM attributable to fires.
Simulating 2020 Creek fire with cloud-resolving E3SM and high-resolution satellite observations
Qi Tang, Lawrence Livermore National Laboratory
The 2020 Creek fire generated pyrocumulonimbus (pyroCb) and injected a large amount of fire smoke into the stratosphere, which contributed to considerable changes in atmospheric radiation and air quality in the western US. The stratospheric aerosols encircled the Northern Hemisphere for months imposing radiative forcing to the Earth system and leading to potential climate impact. In this study, we will leverage the cloud-resolving Energy Exascale Earth System Model (E3SM) and its regionally refined modeling (RRM) capability to enhance the E3SM grid resolution to ~3 km at the California source region. The rest of the globe remains at the standard 100 km resolution for computational efficiency. This RRM configuration explicitly resolves parts of the critical wildfire processes near source regions and quantifies large-scale climate impact of the wildfire event. The Creek fire emissions will be constrained by high-resolution satellite observations based on VIIRS measurements. We will emphasize on the improved representation of interactive chemistry and aerosols (e.g., brown carbon) and their influence on the stratospheric smoke representations. We will also test the simulation sensitivities due to various nudging strategies and a 1-D plume rise parameterization in the 3-km domain.
Spatial Variability in Formaldehyde and Nitrogen Dioxide Diurnal Cycles in the New York City Area
Madankui Tao, Columbia University in the City of New York/ Lamont-Doherty Earth Observatory
Formaldehyde (HCHO) and nitrogen dioxide (NO2) can be remotely sensed by satellite instruments and are relevant to local ozone formation. We examined spatial variations in the diurnal patterns of HCHO and NO2 concentrations using surface monitors, ground-based Pandora spectrometers, and the WRF-CMAQ model (1.33 km) at seven monitoring locations in the NYC metropolitan area and Connecticut shoreline regions during June-August. We observe evidence of the ozone weekend effect (higher ozone on weekends when NOx is lower) at urban sites, while ozone at Westport (CT) and Flax Pond (NY) was higher on weekdays. HCHO concentrations peak at noon at NY Botanical Garden and Flax Pond but around 2 p.m. at Westport. Surface NO2 concentrations exhibit bimodal peaks at all sites except New Haven (CT), where a third peak was noticeable at noontime due to significant local anthropogenic NOx emissions at this near-roadway site. We find discrepancies in the timing of daily maximum near-surface concentrations and column densities of HCHO and NO2, with simulated daily column densities of HCHO and morning NO2 (excluding the evening peak) being delayed by approximately 4 hours compared to peak surface concentrations. Our ongoing analysis aims to determine how emissions and meteorology contribute to the observed spatial variations in photochemical environments that lead to ozone production. This study has implications for the urban-to-rural applications of the TEMPO instrument.
Forecasting daily fire radiative energy using scaled persistence and machine learning for air quality applications
Laura Thapa, University of California, Los Angeles, Atmospheric and Oceanic Sciences, Los Angeles, CA, USA
This work uses random forests and develops new fire indices to forecast daily and sub-daily fire radiative power (FRP) for previously ignited fires in the Western US. FRP forecasts can be used to predict fire emissions, diurnal cycles, and plume heights, all of which are important but still relatively uncertain inputs to the state-of-the art air quality models that help society cope with the negative impacts of smoke. This work seeks to improve upon the persistence assumption used in most air quality models to predict FRP.
The variables which govern wildfire intensity, such as weather, plant and land characteristics, and fire suppression efforts, are monitored via satellite, aircraft, and ground based sensors and are incorporated into reanalysis datasets. We develop a training dataset that consists of fire weather indices, containment percentages, fuel loading and soil moisture estimates, ecosystem-water interaction metrics, and atmospheric stability indices. We also develop an algorithm that aggregates VIIRS fire detections into polygon objects and use these polygons to select portions of the gridded datasets most relevant for each day of the fire. Additionally, we explore relationships between variables in the input space and identify an optimal subset of the input variables for forecasting FRP. We show that random forests methods and scaling previous FRP estimates produce 1-day forecasts of FRP that generally improve upon 1-day persistence forecasts.
Configuration and evaluation of the WRF-Chem air quality simulations over Thailand
Worapop Thongsame, University of Colorado Boulder
Air pollution, especially PM2.5, is a major issue in Thailand. To address this, we aim to configure and evaluate the WRF-Chem to simulate PM2.5 concentrations in Thailand and understand the contributing factors. We assess the model's performance using ground-based observations and satellite data (MODIS AOD and MOPITT CO). The study utilizes the MOZART-MOSAIC scheme with 9 km resolution. Various anthropogenic emission inventories (CAMS, ECLIPSE, REAS, and EDGAR) were evaluated during the off-haze season, revealing that CAMS and ECLIPSE provided comparable PM2.5 concentrations, while REAS and EDGAR overestimated levels.
During the haze season, three biomass-burning inventories (QFED, FINN1.5, and FINN2.5) were assessed alongside the CAMS inventory for anthropogenic emission. FINN1.5 demonstrated the best performance, showing a correlation coefficient of 0.75 when compared to air quality station data and 0.63 for MODIS AOD. FINN2.5 overestimated PM2.5 with a 30% mean fractional error compared with air quality stations and overestimated MODIS AOD in the Northern part of the domain. QFED, on the other hand, underestimated AOD. Overall, FINN1.5 exhibited the best performance, with a correlation coefficient of 0.63 between modeled and MODIS AOD. However, when compared with MOPITT CO, FINN2.5 outperformed FINN1.5. Based on our study, the combination of CAMS and FINN1.5 is the most suitable setup for the WRF-Chem model in Thailand.
Multi-Model Ensemble Forecasts of Hazardous Air Quality Events: Comparisons of Weighted and Unweighted Approaches
Yunyao Li, George Mason University
Will be presented by Daniel Tong on behalf of Yunyao Li
Wildfires are a major source of atmospheric aerosols and trace gases, which can cause hazardous air quality conditions and associated health problems. Accurately predicting wildfire smoke dispersion is challenging due to uncertainties in fire emissions, plume rise, etc. Ensemble forecasting techniques have been increasingly used to improve the predictability. We developed novel ensemble creation methods to improve the ensemble forecast compared to the traditional ensemble mean. 5 operational models, NASA GEOS, NRL NAAPS, NOAA GEFS, HRRR, and NACC-CMAQ model, were used to create the ensemble. Results show that the ensemble mean outperforms each individual model. To further improve the ensemble forecast, we employ statistical methods such as ridge regression, weighted regression, and quantile regression to develop a weighted ensemble. The weighted ensemble reduces the model system error compared to the ensemble mean. Furthermore, the weighted ensemble has a higher hit ratio, weighted success index, and lower false alarm ratio compared to that of individual models and the ensemble mean. This demonstrates that the weighted ensemble is an effective method for reducing forecast uncertainty and improving the accuracy of air quality forecasting during wildfire events. Our findings provide insights into the development of advanced ensemble forecast methods for extreme air quality events, which can aid in decision-making and mitigation efforts for protecting public health.
Extending AIRPACT Simulations to a Third Day
Mohammadamin Vahidi Ghazvini, Washington State University
AIRPACT (Air Indicator Report for Public Awareness and Community Tracking) is a complex air quality forecasting system that is used to predict air pollutants concentrations and depositions, developed at Washington State University over many years. The simulation domain of this model is the northwestern United States, includes the entirety of the states of Washington, Oregon, and Idaho, as well as the northern parts of California, Nevada, and Utah, the western parts of Wyoming and Montana, and the southern parts of the Canadian provinces of British Columbia and Alberta. AIRPACT contains 73530 cells (including 285 horizontal and 258 vertical cells) the size of each grid cell is 4 km by 4 km. Also, AIRPACT has 37 vertical layers.
Currently, AIRPACT forecasts two days (48 hours), and the goal of this research is to increase the forecasting time to 3 days (72 hours). AIRPACT includes the 9 main scripts for simulating the second day, and in this research, we used all of them for simulating the third day. AIRPACT uses 11 main scripts for simulating the first day. Each stage has a main script that contains other sub-scripts.
Advancing Wildfire Research using Large Eddy Simulation (LES) and Machine Learning
Siyuan Wang, CIRES/NOAA/CSL
Wildfires affect weather and climate, with costly impacts on human health and properties. Despite decades of research, wildfires are still challenging to represent in air quality models. One fundamental challenge is that the spatial resolution at which the models are operated is much coarser than the spatial extent of most wildfires. As a result, several key processes in wildfires cannot be explicitly resolved. One of such poorly resolved processes is plume rise. It has been well documented that state-of-the-art plume rise models are subject to large uncertainties, with major impacts on air quality downwind.
In this work, I present the ongoing development of a machine learning emulator for wildfire plume rise. This new framework, trained using a high resolution, turbulence-resolving Large Eddy Simulation (LES) model, emulates the plume rise process considering the impacts of the fire-induced buoyancy, entrainment, and moisture processes. Rigorous measures are taken to mitigate overtraining, and the outcomes are physically sound and interpretable. Preliminary results show that this LES-trained machine learning emulator outperforms a widely used physics-based plume rise model in terms of mean smoke injection height and smoke profile shape. The machine learning emulator is also considerably faster. In summary, this machine learning emulator for plume rise provides an accurate and computationally efficient solution for air quality models and chemistry-climate models.
Slope Angle Impacts on the Turbulence Structure of Daytime Anabatic Winds and Modeling Implications
Ting (Diane) Wang, UC Davis
Buoyantly-driven anabatic winds are induced by radiative surface heating over slopes. They transport air pollutants and moisture, affecting mountain weather via the formation of clouds and orographic precipitation. This study utilizes turbulence observations at multiple levels from two datasets (over a steep Alpine slope in Val Ferret, Switzerland and over a gentle slope of at Granite Mountain in northern Utah) to characterize the mean and turbulence structure of daytime anabatic winds. Observed surface-normal profiles of velocities and temperatures show steep near-surface gradients from both datasets. A jet-shaped profile for streamwise velocity is identified at the steep slope site but not at the gentle slope site likely due to the depth of the anabatic layer. The estimated jet-peak location is ~2.7 m for the steep slope and ~20 m for the gentle slope. We also observe significant momentum and heat flux divergence for anabatic winds at both sites. This is significant because it violates the underlying constant-flux layer assumption for Monin-Obukhov similarity theory, which provides a basis for parameterizing near-surface turbulent flux transport in many numerical weather prediction models. Quantifying the daytime near-surface flux transport and turbulent motion structures with observations over slopes aids in understanding the fundamental physics and improve the existing surface-layer parameterizations in turbulence modeling.
Connecting Aerosol Modeling and Numerical Weather Prediction from Data Assimilation
Shih-Wei Wei, Joint Center for Satellite Data Assimilation and University at Albany
Aerosols affect the radiation budget of the Earth system through the attenuation and the interactions with clouds. This aerosol-cloud-radiation interaction has been studied in climate projections and weather prediction for decades. Its impacts on the context of satellite data assimilation (DA), however, are often neglected despite the considerable reduction in the upwelling radiance at the top of the atmosphere in the thermal infrared (IR) window. As developing the all-sky IR DA, it is worthwhile to understand the advantages and challenges of an aerosol-aware DA framework. This framework also adds another layer of interaction between composition modeling and weather prediction. It further provides insights for coupling Earth DA system.
This study aims to exploit aerosol-affected IR observations in DA. To do this, we identify aerosol-affected observations based on brightness temperature (BT) differences of multiple IR channels. Modeling aerosol mass mixing ratios are then incorporated into the radiance observation operator to calculate the aerosol-affected BTs and Jacobians. The observation errors are dynamically determined by adapting the algorithm from all-sky microwave DA. Using this framework, we conducted an aerosol-aware experiment and compared it with a baseline experiment. Both experiments are based on the National Centers of Environmental Prediction (NCEP) Global Data Assimilation System (GDAS). The impacts on analyses and forecasts will be investigated.
Analyzing Trends in Air Quality During a Drought: A Case Study to Improve Public Health Response to Drought Threats (Withdrew Abstract)
Taylor West, NASA DEVELOP
Air quality has been shown to be significantly correlated with drought severity in the United States, and secondary impacts of droughts such as wildfires and dust storms are known to increase concentrations of airborne particulate matter with adverse effects on human health. This project represents the initial phase of measuring trends in air quality indicators, including Aqua and Terra Moderate Resolution Imaging Spectroradiometer (MODIS) aerosol optical depth (AOD), Suomi NPP Visible Infrared Imaging Radiometer Suite (VIIRS) aerosol optical thickness (AOT), and Environmental Protection Agency’s Air Quality System (AQS) PM2.5 during recent drought conditions in the Pacific Northwest. Using data from the U.S. Drought Monitor (USDM) and Standardized Precipitation Evapotranspiration Index (SPEI), we evaluated these trends across the evolution of drought conditions and constructed maps depicting areas in Oregon and Washington that were vulnerable to changes in air quality during the drought event. By partnering with the University of Nebraska Medical Center’s Water, Climate, and Health Program, NOAA National Integrated Drought Information System, Oregon Health Authority, and Washington State Department of Health, these trend analyses can inform public health departments’ efforts to prepare for and mitigate the effects of drought on human health.
Withdrew Abstract
High Spatiotemporal Resolution Modeling of PM2.5 in West Africa Using Satellite Data and Machine Learning
Benjamin Yang, Columbia University
Exposure to ambient fine particulate matter (PM2.5) is a leading environmental risk factor for premature death. In Africa, surface PM2.5 data is sparse, hindering pollution mitigation plans and human health improvement. NASA satellite observations provide near-complete spatial coverage, but their columnar nature is imperfect representations of surface pollution. To estimate PM2.5 concentrations at high spatiotemporal resolution (1 km^2, daily) across West Africa over the past two decades, we trained, tested, and fine-tuned a machine learning (XGBoost) model with the following data: PM2.5 from about 100 reference-grade and calibrated low-cost monitors, aerosol optical depth from MODIS MAIAC satellite retrievals, five meteorological features from ERA5, and seven tropospheric trace gas column or aerosol property features from TROPOMI/OMI satellite retrievals. Preliminary results show that the model performs reasonably well (r^2 = 0.73, mean absolute error = 11 µg m^-3) in predicting daily PM2.5 compared to observations in six cities across West Africa. Likewise, we will develop a machine learning model focused on Ghana for more localized epidemiological and environmental justice studies. These novel PM2.5 datasets will enable us to identify and explain long-term trends, cycles (seasonal, weekly, and diurnal), and significant sources of PM2.5 in both urban and rural areas. As air quality monitoring networks expand across Africa, the spatial predictions are expected to improve.
CANCELLED: Impact of the Urban Heat Island Effect on Simulating Air Quality in Seoul, South Korea
Katherine (Katie) Travis, NASA Langley Research Center
In Seoul, it has been shown that the urban heat island effect deepens the nighttime boundary layer, reducing ozone titration at night, and strengthens the urban breeze, bringing in more ozone from the surrounding areas. Here, we apply the urban heat island effect to simulating the 2016 NIER/NASA Korea-United States Air Quality (KORUS-AQ) field campaign using the newly developed WRF-GC model that incorporates the GEOS-Chem chemical mechanism and Harmonized Emissions Component (HEMCO) with the Weather Research and Forecasting (WRF) model and its urban physics schemes. We assess how the inclusion of the urban heat island effect impacts simulations of the diurnal cycle of surface and column pollutants and whether including urban physics improves model comparisons against the detailed aircraft chemical observations. We also analyze whether the urban heat island effect can improve long-standing model overestimates of nitrate due to incorrect nighttime chemistry driven by insufficient nighttime mixing.
CANCELLED: Forecasting hourly wildfire emissions using a modulated persistence approach based on an hourly wildfire potential index
Johana Romero-Alvarez, Cooperative Institute for Research in Environmental Sciences, University of Colorado at Boulder/NOAA Global Systems Laboratory
As wildfires increase in frequency and severity, smoke forecasting becomes fundamental to help minimize exposure, improve weather forecasting, and guide wildfire-fighting operations. Most smoke and air quality forecast models assume a persistence approach in which the latest satellite-based biomass burning emissions estimates are modulated by a parameterized climatological diurnal cycle during the forecast duration. The only variable to account for weather impact on smoke emissions is the effect of precipitation, which is simplistically included in some of the models. NOAA's Global Systems Laboratory is developing a new experimental weather forecast model, the Rapid-Refresh Forecasting System (RRFS), that covers the CONUS domain at 3 km resolution. The model also simulates 3D transport and mixing of smoke emissions. Here, an hourly wildfire potential (HWP) index computed using predicted 10-m wind gust, surface dewpoint depression, and soil moisture availability is used to modulate persistence-based forecasted wildfire emissions estimates within the RRFS smoke and dust (RRFS-SD) model. The method is compared against the persistence approach for two fire seasons, 2019, which coincides with the FIREX-AQ campaign and represents a low-intensity fire season, and 2020, characterized by severe fires in the western US. The model performance is evaluated using ground-based PM2.5 and aerosol optical depth observations and in-situ measurements acquired by an aircraft during FIREX-AQ.
CANCELLED: Evaluation of the Air Quality in the Vicinity of Quarrying at Ebonyi State, Nigeria
SAMUEL AKPAN, Federal College of Fisheries and Marine Technology, Victoria Island, Lagos, Nigeria
In Ebonyi State, Nigeria, numerous quarries contribute considerably to the growth of the economy. However, these sectors have had a significant effect on the environment, and one of those impacts is air pollution. Extech Model VPC300 and Aeroqual 500 series were used to measure the state of the air to determine the consequences of quarry dust on the environment. The quarry regions and the area around them were found to be much more polluted than indicated by international standards for PM2.5, PM10, and NO2. There is a strong correlation matrix between the detected quarry contaminants, the weather, and distant measurements. To reduce the amount of dust released into the atmosphere, it is advised to use modern, environmentally friendly crushing equipment with built-in dust collectors. It is also advised to create a green belt using trees that can withstand pollution around the quarrying locations to lessen the impact of air pollution.
CANCELLED: Quantification of crop residue burning using WRF-Chem model over North Indian region
Ummed Singh Saharan, National Physical Laboratory, New Delhi, India
Intensive Crop Residue Burning (CRB) in north India causes severe air pollution episodes over the Indo-Gangetic Plain (IGP), India, every year during October-November. Present study has quantified the role of the CRB using the Weather Research and Forecasting model coupled with Chemistry (WRF-Chem) using recent anthropogenic (EDGARv5) and biomass burning emissions (FINNv2.4) inventories and the MOZART-MOSAIC chemical scheme. First, we have investigated long term CRB data (2012 to 2019) to find out the dominant CRB areas, period of burning, and hotspot districts in Punjab and Haryana. Then, we have utilized WRF-Chem with different sensitivity runs to quantify the role of the CRB. Hotspot districts contributed ~80% and ~50% of total fire counts in Haryana and Punjab, respectively. PM₂.₅ was well captured with NMB < 0.2 and R > 0.6 over the majority of sites across the domain. The hotspot districts contributed about 70% of total CRB-induced PM₂.₅ enhancement at the western, central, and eastern sites, and approximately 50% at the northern sites. We could save ~18k lives by eliminating CRB from the entire domain and policymakers can address this issue by focusing on hotspot districts first.