Your search keyword '"Kowalewski, Matthew G."' showing total 30 results

1. Overview of the Lake Michigan Ozone Study 2017

Author

Stanier, Charles O., Pierce, R. Bradley, Abdi-Oskouei, Maryam, Adelman, Zachariah E., Al-Saadi, Jay, Alwe, Hariprasad D., Bertram, Timothy H., Carmichael, Gregory R., Christiansen, Megan B., Cleary, Patricia A., Czarnetzki, Alan C., Dickens, Angela F., Fuoco, Marta A., Hughes, Dagen D., Hupy, Joseph P., Janz, Scott J., Judd, Laura M., Kenski, Donna, Kowalewski, Matthew G., Long, Russell W., Millet, Dylan B., Novak, Gordon, Roozitalab, Behrooz, Shaw, Stephanie L., Stone, Elizabeth A., Szykman, James, Valin, Lukas, Vermeuel, Michael, Wagner, Timothy J., Whitehill, Andrew R., and Williams, David J.

Published

2021

2. High-resolution mapping of SO2 using airborne observations from the GeoTASO instrument during the KORUS-AQ field study: PCA-based vertical column retrievals

Author

Chong, Heesung, Lee, Seoyoung, Kim, Jhoon, Jeong, Ukkyo, Li, Can, Krotkov, Nickolay A., Nowlan, Caroline R., Al-Saadi, Jassim A., Janz, Scott J., Kowalewski, Matthew G., Ahn, Myoung-Hwan, Kang, Mina, Joiner, Joanna, Haffner, David P., Hu, Lu, Castellanos, Patricia, Huey, L. Gregory, Choi, Myungje, Song, Chul H., Han, Kyung Man, and Koo, Ja-Ho

Published

2020

3. Diurnal changes of remote sensing reflectance over Chesapeake Bay: Observations from the Airborne Compact Atmospheric Mapper

Author

Zhang, Minwei, Hu, Chuanmin, Cannizzaro, Jennifer, Kowalewski, Matthew G., and Janz, Scott J.

Published

2018

4. The ARGOS Instrument for Stratospheric Aerosol Measurements.

Author

DeLand, Matthew T., Kowalewski, Matthew G., Colarco, Peter R., and Ramos-Izquierdo, Luis

Subjects

*STRATOSPHERIC aerosols, *ATMOSPHERIC aerosols, *FORCE & energy, *AEROSOLS, *ORBITS (Astronomy), *ENERGY budget (Geophysics)

Abstract

Atmospheric aerosols represent an important component of the Earth's climate system because they can contribute both positive and negative forcing to the energy budget. We are developing the Aerosol Radiometer for Global Observations of the Stratosphere (ARGOS) instrument to provide improved measurements of stratospheric aerosols in a compact package. ARGOS makes limb scattering measurements from space in eight directions simultaneously, using two near-IR wavelengths for each viewing direction. The combination of forward and backward scattering views along the orbit track gives additional information to constrain the aerosol phase function and size distribution. Cross-track views provide expanded spatial coverage. ARGOS will have a demonstration flight through a hosted payload provider in the fall of 2024. The instrument has completed pre-launch environmental testing and radiometric characterization tests. The hosted payload approach offers advantages in size, weight, and power margins for instrument design compared to other approaches, with significant benefits in terms of reducing infrastructure requirements for the instrument team. [ABSTRACT FROM AUTHOR]

Published

2024

5. Nitrogen Dioxide Observations from the Geostationary Trace Gas and Aerosol Sensor Optimization (GeoTaso) Airborne Instrument: Retrieval Algorithm and Measurements During DISCOVER-AQ Texas 2013

Author

Nowlan, Caroline R, Liu, Xiong, Leitch, James W, Chance, Kelly, Abad, Gonzalo Gonzalez, Liu, Xiaojun, Zoogman, Peter, Cole, Joshua, Delker, Thomas, Good, William, Murcray, Frank, Ruppert, Lyle, Soo, Daniel, Fowlette-Cook, Melanie B, Janz, Scott J, Kowalewski, Matthew G, Loughner, Christopher P, Pickering, Kenneth E, Herman, Jay R, Beaver, Melina R, Long, Russell W, Szykman, James J, Judd, Laura M, Kelley, Paul, Luke, Winston T, Ren, Xinrong, and Al-Saadi, Jassim A

Subjects

Environment Pollution, Geosciences (General)

Abstract

The Geostationary Trace gas and Aerosol Sensor Optimization (GeoTASO) airborne instrument is a test bed for upcoming air quality satellite instruments that will measure backscattered ultraviolet, visible and near-infrared light from geostationary orbit. GeoTASO flew on the NASA Falcon aircraft in its first intensive field measurement campaign during the Deriving Information on Surface Conditions from Column and Vertically Resolved Observations Relevant to Air Quality (DISCOVER-AQ) Earth Venture Mission over Houston, Texas, in September 2013. Measurements of backscattered solar radiation between 420 and 465 nm collected on 4 days during the campaign are used to determine slant column amounts of NO2 at 250 m x 250 m spatial resolution with a fitting precision of 2.2 x 10(exp 15) molecules/sq cm. These slant columns are converted to tropospheric NO2 vertical columns using a radiative transfer model and trace gas profiles from the Community Multiscale Air Quality (CMAQ) model. Total column NO2 from GeoTASO is well correlated with ground-based Pandora observations (r = 0.90 on the most polluted and cloud-free day of measurements and r = 0.74 overall), with GeoTASO NO2 slightly higher for the most polluted observations. Surface NO2 mixing ratios inferred from GeoTASO using the CMAQ model show good correlation with NO2 measured in situ at the surface during the campaign (r = 0.85). NO2 slant columns from GeoTASO also agree well with preliminary retrievals from the GEO-CAPE Airborne Simulator (GCAS) which flew on the NASA King Air B200 (r = 0.81, slope = 0.91). Enhanced NO2 is resolvable over areas of traffic NOx emissions and near individual petrochemical facilities.

Published

2016

6. Comprehensive evaluations of diurnal NO2 measurements during DISCOVER-AQ 2011: effects of resolution-dependent representation of NOx emissions

Author

Li, Jianfeng, Wang, Yuhang, Zhang, Ruixiong, Smeltzer, Charles, Weinheimer, Andrew, Herman, Jay, Boersma, K. Folkert, Celarier, Edward A., Long, Russell W., Szykman, James J., Delgado, Ruben, Thompson, Anne M., Knepp, Travis N., Lamsal, Lok N., Janz, Scott J., Kowalewski, Matthew G., Liu, Xiong, and Nowlan, Caroline R.

Abstract

Nitrogen oxides (NOx = NO + NO2) play a crucial role in the formation of ozone and secondary inorganic and organic aerosols, thus affecting human health, global radiation budget, and climate. The diurnal and spatial variations in NO2 are functions of emissions, advection, deposition, vertical mixing, and chemistry. Their observations, therefore, provide useful constraints in our understanding of these factors. We employ a Regional chEmical and trAnsport model (REAM) to analyze the observed temporal (diurnal cycles) and spatial distributions of NO2 concentrations and tropospheric vertical column densities (TVCDs) using aircraft in situ measurements and surface EPA Air Quality System (AQS) observations as well as the measurements of TVCDs by satellite instruments (OMI: the Ozone Monitoring Instrument; GOME-2A: Global Ozone Monitoring Experiment – 2A), ground-based Pandora, and the Airborne Compact Atmospheric Mapper (ACAM) instrument in July 2011 during the DISCOVER-AQ campaign over the Baltimore–Washington region. The model simulations at 36 and 4 km resolutions are in reasonably good agreement with the regional mean temporospatial NO2 observations in the daytime. However, we find significant overestimations (underestimations) of model-simulated NO2 (O3) surface concentrations during nighttime, which can be mitigated by enhancing nocturnal vertical mixing in the model. Another discrepancy is that Pandora-measured NO2 TVCDs show much less variation in the late afternoon than simulated in the model. The higher-resolution 4 km simulations tend to show larger biases compared to the observations due largely to the larger spatial variations in NOx emissions in the model when the model spatial resolution is increased from 36 to 4 km. OMI, GOME-2A, and the high-resolution aircraft ACAM observations show a more dispersed distribution of NO2 vertical column densities (VCDs) and lower VCDs in urban regions than corresponding 36 and 4 km model simulations, likely reflecting the spatial distribution bias of NOx emissions in the National Emissions Inventory (NEI) 2011.

Published

2021

7. Evaluating Sentinel-5P TROPOMI tropospheric NO2 column densities with airborne and Pandora spectrometers near New York City and Long Island Sound

Author

Judd, Laura M., Al-Saadi, Jassim A., Szykman, James J., Valin, Lukas C., Janz, Scott J., Kowalewski, Matthew G., Eskes, Henk J., Veefkind, J. Pepijn, Cede, Alexander, Mueller, Moritz, Gebetsberger, Manuel, Swap, Robert, Pierce, R. Bradley, Nowlan, Caroline R., Abad, Gonzalo González, Nehrir, Amin, and Williams, David

Abstract

Airborne and ground-based Pandora spectrometer NO2 column measurements were collected during the 2018 Long Island Sound Tropospheric Ozone Study (LISTOS) in the New York City/Long Island Sound region, which coincided with early observations from the Sentinel-5P TROPOspheric Monitoring Instrument (TROPOMI) instrument. Both airborne- and ground-based measurements are used to evaluate the TROPOMI NO2 Tropospheric Vertical Column (TrVC) product v1.2 in this region, which has high spatial and temporal heterogeneity in NO2. First, airborne and Pandora TrVCs are compared to evaluate the uncertainty of the airborne TrVC and establish the spatial representativeness of the Pandora observations. The 171 coincidences between Pandora and airborne TrVCs are found to be highly correlated (r2= 0.92 and slope of 1.03), with the largest individual differences being associated with high temporal and/or spatial variability. These reference measurements (Pandora and airborne) are complementary with respect to temporal coverage and spatial representativity. Pandora spectrometers can provide continuous long-term measurements but may lack areal representativity when operated in direct-sun mode. Airborne spectrometers are typically only deployed for short periods of time, but their observations are more spatially representative of the satellite measurements with the added capability of retrieving at subpixel resolutions of 250 m × 250 m over the entire TROPOMI pixels they overfly. Thus, airborne data are more correlated with TROPOMI measurements (r2=0.96) than Pandora measurements are with TROPOMI (r2=0.84). The largest outliers between TROPOMI and the reference measurements appear to stem from too spatially coarse a priori surface reflectivity (0.5∘) over bright urban scenes. In this work, this results during cloud-free scenes that, at times, are affected by errors in the TROPOMI cloud pressure retrieval impacting the calculation of tropospheric air mass factors. This factor causes a high bias in TROPOMI TrVCs of 4 %–11 %. Excluding these cloud-impacted points, TROPOMI has an overall low bias of 19 %–33 % during the LISTOS timeframe of June–September 2018. Part of this low bias is caused by coarse a priori profile input from the TM5-MP model; replacing these profiles with those from a 12 km North American Model–Community Multiscale Air Quality (NAMCMAQ) analysis results in a 12 %–14 % increase in the TrVCs. Even with this improvement, the TROPOMI-NAMCMAQ TrVCs have a 7 %–19 % low bias, indicating needed improvement in a priori assumptions in the air mass factor calculation. Future work should explore additional impacts of a priori inputs to further assess the remaining low biases in TROPOMI using these datasets.

Published

2020

8. Comparison of Spectral Radiance Calibration Techniques Used for Backscatter Ultraviolet Satellite Instruments

Author

Kowalewski, Matthew G and Janz, Scott

Subjects

Optics, Instrumentation And Photography

Abstract

Methods for determining the absolute radiometric calibration sensitivities of backscatter ultraviolet (BUV) satellite instruments are compared as part of an effort to minimize pre-launch calibration errors. An internally illuminated integrating sphere source has been used for the Shuttle Solar BUV (SSBUV), Total Ozone Mapping Spectrometer (TOMS), Ozone Mapping Instrument (OMI), and Global Ozone Monitoring Experiment 2 (GOME-2) using standardized procedures traceable to national standards. These sphere-based sensitivities agree to within three percent [k equals 2] relative to calibrations performed using an external diffuser illuminated by standard irradiance sources, the customary radiance calibration method for BUV instruments. The uncertainty for these calibration techniques as implemented at the NASA Goddard Space Flight Centers Radiometric Calibration and Development Laboratory is shown to be 4 percent at 250nm [k equals 2] when using a single traceable calibration standard. Significant reduction in the uncertainty of nearly 1 percent is demonstrated when multiple calibration standards are used.

Published

2014

9. Development and Performance of a Filter Radiometer Monitor System for Integrating Sphere Sources

Author

Ding, Leibo, Kowalewski, Matthew G, Cooper, John W, Smith, GIlbert R, Barnes, Robert A, Waluschka, Eugene, and Butler, James J

Subjects

Instrumentation And Photography

Abstract

The NASA Goddard Space Flight Center (GSFC) Radiometric Calibration Laboratory (RCL) maintains several large integrating sphere sources covering the visible to the shortwave infrared wavelength range. Two critical, functional requirements of an integrating sphere source are short and long-term operational stability and repeatability. Monitoring the source is essential in determining the origin of systemic errors, thus increasing confidence in source performance and quantifying repeatability. If monitor data falls outside the established parameters, this could be an indication that the source requires maintenance or re-calibration against the National Institute of Science and Technology (NIST) irradiance standard. The GSFC RCL has developed a Filter Radiometer Monitoring System (FRMS) to continuously monitor the performance of its integrating sphere calibration sources in the 400 to 2400nm region. Sphere output change mechanisms include lamp aging, coating (e.g. BaSO4) deterioration, and ambient water vapor level. The Filter Radiometer Monitor System (FRMS) wavelength bands are selected to quantify changes caused by these mechanisms. The FRMS design and operation are presented, as well as data from monitoring four of the RCL s integrating sphere sources.

Published

2011

10. Polar Mesospheric Clouds (PMCs) Observed by the Ozone Monitoring Instrument (OMI) on Aura

Author

DeLand, Matthew T, Shettle, Eric P, Levelt, Pieternel F, and Kowalewski, Matthew G

Subjects

Meteorology And Climatology

Abstract

Backscattered ultraviolet (BUV) instruments designed for measuring stratospheric ozone profiles have proven to be robust tools for observing polar mesospheric clouds (PMCs). These measurements are available for more than 30 years, and have been used to demonstrate the existence of long-term variations in PMC occurrence frequency and brightness. The Ozone Monitoring Instrument (OMI) on the EOS Aura satellite provides new and improved capabilities for PMC characterization. OMI uses smaller pixels than previous BUV instruments, which increases its ability to identify PMCs and discern more spatial structure, and its wide cross-track viewing swath provides full polar coverage up to 90 latitude every day in both hemispheres. This cross-track coverage allows the evolution of PMC regions to be followed over several consecutive orbits. Localized PMC variations determined from OMI measurements are consistent with coincident SBUV/2 measurements. Nine seasons of PMC observations from OMI are now available, and clearly demonstrate the advantages of these measurements for PMC analysis.

Published

2010

11. Evaluating the impact of spatial resolution on tropospheric NO2 column comparisons within urban areas using high-resolution airborne data

Author

Judd, Laura M., Al-Saadi, Jassim A., Janz, Scott J., Kowalewski, Matthew G., Pierce, R. Bradley, Szykman, James J., Valin, Lukas C., Swap, Robert, Cede, Alexander, Mueller, Moritz, Tiefengraber, Martin, Abuhassan, Nader, and Williams, David

Abstract

NASA deployed the GeoTASO airborne UV–visible spectrometer in May–June 2017 to produce high-resolution (approximately 250 m×250 m) gapless NO2 datasets over the western shore of Lake Michigan and over the Los Angeles Basin. The results collected show that the airborne tropospheric vertical column retrievals compare well with ground-based Pandora spectrometer column NO2 observations (r2=0.91 and slope of 1.03). Apparent disagreements between the two measurements can be sensitive to the coincidence criteria and are often associated with large local variability, including rapid temporal changes and spatial heterogeneity that may be observed differently by the sunward-viewing Pandora observations. The gapless mapping strategy executed during the 2017 GeoTASO flights provides data suitable for averaging to coarser areal resolutions to simulate satellite retrievals. As simulated satellite pixel area increases to values typical of TEMPO (Tropospheric Emissions: Monitoring Pollution), TROPOMI (TROPOspheric Monitoring Instrument), and OMI (Ozone Monitoring Instrument), the agreement with Pandora measurements degraded, particularly for the most polluted columns as localized large pollution enhancements observed by Pandora and GeoTASO are spatially averaged with nearby less-polluted locations within the larger area representative of the satellite spatial resolutions (aircraft-to-Pandora slope: TEMPO scale =0.88; TROPOMI scale =0.77; OMI scale =0.57). In these two regions, Pandora and TEMPO or TROPOMI have the potential to compare well at least up to pollution scales of 30×1015 molecules cm−2. Two publicly available OMI tropospheric NO2 retrievals are found to be biased low with respect to these Pandora observations. However, the agreement improves when higher-resolution a priori inputs are used for the tropospheric air mass factor calculation (NASA V3 standard product slope =0.18 and Berkeley High Resolution product slope =0.30). Overall, this work explores best practices for satellite validation strategies with Pandora direct-sun observations by showing the sensitivity to product spatial resolution and demonstrating how the high-spatial-resolution NO2 data retrieved from airborne spectrometers, such as GeoTASO, can be used with high-temporal-resolution ground-based column observations to evaluate the influence of spatial heterogeneity on validation results.

Published

2019

12. First Top-Down Estimates of Anthropogenic NOxEmissions Using High-Resolution AirborneRemote Sensing Observations

Author

Souri, Amir H., Choi, Yunsoo, Pan, Shuai, Curci, Gabriele, Nowlan, Caroline R., Janz, Scott J., Kowalewski, Matthew G., Liu, Junjie, Herman, Jay, and Weinheimer, Andrew J.

Abstract

A number of satellite-based instruments have become an essential part of monitoring emissions.Despite sound theoretical inversion techniques, the insufficient samples and the footprint size of currentobservations have introduced an obstacle to narrow the inversion window for regional models. These keylimitations can be partially resolved by a set of modest high-quality measurements from airborne remotesensing. This study illustrates the feasibility of nitrogen dioxide (NO₂) columns from the Geostationary Coastaland Air Pollution Events Airborne Simulator (GCAS) to constrain anthropogenic NOxemissions in theHouston-Galveston-Brazoria area. We convert slant column densities to vertical columns using a radiativetransfer model with (i) NO₂profiles from a high-resolution regional model (1 × 1 km2) constrained by P-3Baircraft measurements, (ii) the consideration of aerosol optical thickness impacts on radiance at NO₂absorption line, and (iii) high-resolution surface albedo constrained by ground-based spectrometers. Wecharacterize errors in the GCAS NO₂columns by comparing them to Pandora measurements andfind astriking correlation (r>0.74) with an uncertainty of 3.5 × 1015molecules cm 2. On 9 of 10 total days, theconstrained anthropogenic emissions by a Kalmanfilter yield an overall 2–50% reduction in polluted areas,partly counterbalancing the well-documented positive bias of the model. The inversion, however, boostsemissions by 94% in the same areas on a day when an unprecedented local emissions event potentiallyoccurred, significantly mitigating the bias of the model. The capability of GCAS at detecting such an eventensures the significance of forthcoming geostationary satellites for timely estimates of top-down emissions.

Published

2018

13. Top-down estimates of anthropogenic VOC emissions in South Korea using formaldehyde vertical column densities from aircraft during the KORUS-AQ campaign.

Author

Hyeong-Ahn Kwon, Rokjin J. Park, Yujin J. Oak, Nowlan, Caroline R., Janz, Scott J., Kowalewski, Matthew G., Fried, Alan, Walega, James, Bates, Kelvin H., Jinkyul Choi, Blake, Donald R., Wisthaler, Armin, and Jung-Hun Woo

Published

2021

14. Comprehensive evaluations of diurnal NO2 measurements during DISCOVER-AQ 2011: Effects of resolution dependent representation of NOx emissions.

Author

Jianfeng Li, Yuhang Wang, Ruixiong Zhang, Smeltzer, Charles, Weinheimer, Andrew, Herman, Jay, Boersma, K. Folkert, Celarier, Edward A., Long, Russell W., Szykman, James J., Delgado, Ruben, Thompson, Anne M., Knepp, Travis N., Lamsal, Lok N., Janz, Scott J., Kowalewski, Matthew G., Xiong Liu, and Nowlan, Caroline R.

Abstract

Nitrogen oxides (NOx = NO + NO2) play a crucial role in the formation of ozone and secondary inorganic and organic aerosols, thus affecting human health, global radiation budget, and climate. The diurnal and spatial variations of NO2 are functions of emissions, advection, deposition, vertical mixing, and chemistry. Their observations, therefore, provide useful constraints in our understanding of these factors. We employ a Regional chEmical and trAnsport model (REAM) to analyze the observed temporal (diurnal cycles) and spatial distributions of NO2 concentrations and tropospheric vertical column densities (TVCDs) using aircraft in situ measurements, surface EPA Air Quality System (AQS) observations, as well as the measurements of TVCDs by satellite instruments (OMI: the Ozone Monitoring Instrument; and GOME-2A: Global Ozone Monitoring Experiment - 2A), ground-based Pandora, and the Airborne Compact Atmospheric Mapper (ACAM) instrument, in July 2011 during the DISCOVER-AQ campaign over the Baltimore-Washington region. The model simulations at 36- and 4-km resolutions are in reasonably good agreement with the temporospatial NO2 observations in the daytime. However, nighttime mixing in the model needs to be enhanced to reproduce the observed NO2 diurnal cycle in the model. Another discrepancy is that Pandora measured NO2 TVCDs show much less variation in the late afternoon than simulated in the model. Relative to the 36-km model simulations, the 4-km model results show larger biases compared to the observations due largely to the larger spatial variations of NO2 in the model when the spatial resolution is increased from 36 to 4 km, although the biases are often comparable to the ranges of the observations. The high-resolution aircraft ACAM observations show a more dispersed distribution of NO2 vertical column densities (VCDs) and lower VCDs in urban regions than 4-km model simulations, reflecting likely the spatial distribution bias of NOx emissions in the National Emissions Inventory (NEI) 2011 at high resolution. [ABSTRACT FROM AUTHOR]

Published

2021

15. Evaluating Sentinel-5P TROPOMI tropospheric NO2 column densities with airborne and Pandora spectrometers near New York City and Long Island Sound.

Author

Judd, Laura M., Al-Saadi, Jassim A., Szykman, James J., Valin, Lukas C., Janz, Scott J., Kowalewski, Matthew G., Eskes, Henk J., Veefkind, J. Pepijn, Cede, Alexander, Mueller, Moritz, Gebetsberger, Manuel, Swap, Robert, Pierce, R. Bradley, Nowlan, Caroline R., Abad, Gonzalo González, Nehrir, Amin, and Williams, David

Subjects

AIRBORNE lasers, SPECTROMETERS, TROPOSPHERIC ozone, AIR masses, AIR quality, AIRBORNE-based remote sensing

Abstract

Airborne and ground-based Pandora spectrometer NO 2 column measurements were collected during the 2018 Long Island Sound Tropospheric Ozone Study (LISTOS) in the New York City/Long Island Sound region, which coincided with early observations from the Sentinel-5P TROPOspheric Monitoring Instrument (TROPOMI) instrument. Both airborne- and ground-based measurements are used to evaluate the TROPOMI NO 2 Tropospheric Vertical Column (TrVC) product v1.2 in this region, which has high spatial and temporal heterogeneity in NO 2. First, airborne and Pandora TrVCs are compared to evaluate the uncertainty of the airborne TrVC and establish the spatial representativeness of the Pandora observations. The 171 coincidences between Pandora and airborne TrVCs are found to be highly correlated (r2= 0.92 and slope of 1.03), with the largest individual differences being associated with high temporal and/or spatial variability. These reference measurements (Pandora and airborne) are complementary with respect to temporal coverage and spatial representativity. Pandora spectrometers can provide continuous long-term measurements but may lack areal representativity when operated in direct-sun mode. Airborne spectrometers are typically only deployed for short periods of time, but their observations are more spatially representative of the satellite measurements with the added capability of retrieving at subpixel resolutions of 250 m × 250 m over the entire TROPOMI pixels they overfly. Thus, airborne data are more correlated with TROPOMI measurements (r2=0.96) than Pandora measurements are with TROPOMI (r2=0.84). The largest outliers between TROPOMI and the reference measurements appear to stem from too spatially coarse a priori surface reflectivity (0.5 ∘) over bright urban scenes. In this work, this results during cloud-free scenes that, at times, are affected by errors in the TROPOMI cloud pressure retrieval impacting the calculation of tropospheric air mass factors. This factor causes a high bias in TROPOMI TrVCs of 4 %–11 %. Excluding these cloud-impacted points, TROPOMI has an overall low bias of 19 %–33 % during the LISTOS timeframe of June–September 2018. Part of this low bias is caused by coarse a priori profile input from the TM5-MP model; replacing these profiles with those from a 12 km North American Model–Community Multiscale Air Quality (NAMCMAQ) analysis results in a 12 %–14 % increase in the TrVCs. Even with this improvement, the TROPOMI-NAMCMAQ TrVCs have a 7 %–19 % low bias, indicating needed improvement in a priori assumptions in the air mass factor calculation. Future work should explore additional impacts of a priori inputs to further assess the remaining low biases in TROPOMI using these datasets. [ABSTRACT FROM AUTHOR]

Published

2020

16. Evaluating Sentinel-5P TROPOMI tropospheric NO2 column densities with airborne and Pandora spectrometers near New York City and Long Island Sound.

Author

Judd, Laura M., Al-Saadi, Jassim A., Szykman, James J., Valin, Lukas C., Janz, Scott J., Kowalewski, Matthew G., Eskes, Henk J., Veefkind, J. Pepijn, Cede, Alexander, Mueller, Moritz, Gebetsberger, Manuel, Swap, Robert, Pierce, R. Bradley, Nowlan, Caroline R., Abad, Gonzalo González, Nehrir, Amin, and Williams, David

Subjects

SPECTROMETERS, TROPOSPHERIC ozone, RADIOMETERS, AIR masses

Abstract

Abundant NO[sub 2] column measurements from airborne and ground-based Pandora spectrometers were collected as part of the 2018 Long Island Sound Tropospheric Ozone Study (LISTOS) in the New York City/Long Island Sound region and coincided with early measurements from the Sentinel-5P TROPOMI instrument. Both airborne- and ground-based measurements are used to evaluate the TROPOspheric Monitoring Instrument (TROPOMI) NO[sub 2] Tropospheric Vertical Column (TrVC) product v1.2 in this region, which has high spatial and temporal heterogeneity in NO[sub 2]. First, airborne and Pandora TrVCs are compared to evaluate the uncertainty of the airborne TrVC and establish the spatial representativeness of the Pandora observations. The 171 coincidences between Pandora and airborne TrVCs are found to be highly correlated (r[sup 2]=0.92 and slope of 1.03) with the biggest individual differences being associated with high temporal and/or spatial variability. These reference measurements (Pandora and airborne) are complementary with respect to temporal coverage and spatial representivity. Pandora spectrometers can provide continuous long-term measurements but may lack areal representivity when operated in direct-sun mode. Airborne spectrometers are typically only deployed for short periods of time, but their observations are more spatially representative of the satellite measurements with the added capability of retrieving at subpixel resolutions of 250 m × 250 m over the entire TROPOMI pixels they overfly. Thus, airborne data are more correlated with TROPOMI measurements (r[sup 2]=0.96) than Pandora measurements are with TROPOMI (r[sup 2]=0.84). The largest outliers between TROPOMI and the reference measurements are caused by errors in the TROPOMI retrieval of cloud pressure impacting the calculation of tropospheric air mass factors in cloud-free scenes. This factor causes a high bias in TROPOMI TrVCs of 4-11 %. Excluding these cloud-impacted points, TROPOMI has an overall low bias of 19-33% during the LISTOS timeframe of June-September 2018. Part of this low bias is caused by coarse a priori profile input from TM5-MP model; replacing these profiles with those from a 12 km NAMCMAQ analysis results in a 12-14 % increase in the TrVCs. Even with this improvement, the TROPOMI-NAMCMAQ TrVCs have a 7-19 % low bias, indicating needed improvement in a priori assumptions in the air mass factor calculation. Future work should explore additional impacts of a priori inputs to further assess the remaining low biases in TROPOMI using these datasets. [ABSTRACT FROM AUTHOR]

Published

2020

17. Field calibration techniques used to characterize the radiometric stability of the GEO-CAPE Airborne Simulator (GCAS).

Author

Pantina, Peter, Kowalewski, Matthew G., Janz, Scott J., and Sanxiong Xiong

Published

2019

18. Evaluating the impact of spatial resolution on tropospheric NO2 column comparisons within urban areas using high-resolution airborne data.

Author

Judd, Laura M., Al-Saadi, Jassim A., Janz, Scott J., Kowalewski, Matthew G., Pierce, R. Bradley, Szykman, James J., Valin, Lukas C., Swap, Robert, Cede, Alexander, Mueller, Moritz, Tiefengraber, Martin, Abuhassan, Nader, and Williams, David

Subjects

CITIES & towns, EMISSIONS (Air pollution), POLLUTION monitoring, AIR masses, ORBITS of artificial satellites

Abstract

NASA deployed the GeoTASO airborne UV–visible spectrometer in May–June 2017 to produce high-resolution (approximately 250m×250m) gapless NO2 datasets over the western shore of Lake Michigan and over the Los Angeles Basin. The results collected show that the airborne tropospheric vertical column retrievals compare well with ground-based Pandora spectrometer column NO2 observations (r2=0.91 and slope of 1.03). Apparent disagreements between the two measurements can be sensitive to the coincidence criteria and are often associated with large local variability, including rapid temporal changes and spatial heterogeneity that may be observed differently by the sunward-viewing Pandora observations. The gapless mapping strategy executed during the 2017 GeoTASO flights provides data suitable for averaging to coarser areal resolutions to simulate satellite retrievals. As simulated satellite pixel area increases to values typical of TEMPO (Tropospheric Emissions: Monitoring Pollution), TROPOMI (TROPOspheric Monitoring Instrument), and OMI (Ozone Monitoring Instrument), the agreement with Pandora measurements degraded, particularly for the most polluted columns as localized large pollution enhancements observed by Pandora and GeoTASO are spatially averaged with nearby less-polluted locations within the larger area representative of the satellite spatial resolutions (aircraft-to-Pandora slope: TEMPO scale =0.88 ; TROPOMI scale =0.77 ; OMI scale =0.57). In these two regions, Pandora and TEMPO or TROPOMI have the potential to compare well at least up to pollution scales of 30×1015 molecules cm -2. Two publicly available OMI tropospheric NO2 retrievals are found to be biased low with respect to these Pandora observations. However, the agreement improves when higher-resolution a priori inputs are used for the tropospheric air mass factor calculation (NASA V3 standard product slope =0.18 and Berkeley High Resolution product slope =0.30). Overall, this work explores best practices for satellite validation strategies with Pandora direct-sun observations by showing the sensitivity to product spatial resolution and demonstrating how the high-spatial-resolution NO2 data retrieved from airborne spectrometers, such as GeoTASO, can be used with high-temporal-resolution ground-based column observations to evaluate the influence of spatial heterogeneity on validation results. [ABSTRACT FROM AUTHOR]

Published

2019

19. Evaluating the impact of spatial resolution on tropospheric NO2 column comparisons within urban areas using high-resolution airborne data.

Author

Judd, Laura M., Al-Saadi, Jassim A., Janz, Scott J., Kowalewski, Matthew G., Pierce, R. Bradley, Szykman, James J., Valin, Lukas C., Swap, Robert, Cede, Alexander, Mueller, Moritz, Tiefengraber, Martin, Abuhassan, Nader, and Williams, David

Subjects

CITIES & towns, AIR masses, SPECTROMETERS, BEST practices

Abstract

NASA deployed an airborne UV/Visible spectrometer, GeoTASO, in May-June 2017 to produce high resolution (approximately 250 x 250 m), gapless NO2 datasets over the western shore of Lake Michigan and over the Los Angeles Basin. Results show that the airborne tropospheric vertical column retrievals compare well with ground-based Pandora spectrometer column NO2 observations (r² = 0.91 and slope of 1.03). Apparent disagreements between the two measurements can be sensitive to the coincidence criteria and are often associated with large local variability, including rapid temporal changes and also spatial heterogeneity that may be observed differently by the sunward viewing Pandora observations. The gapless mapping strategy executed during the 2017 GeoTASO flights provides data suitable for averaging to coarser areal resolutions to simulate satellite retrievals. As simulated satellite pixel area increases to values typical of TEMPO, TROPOMI, and OMI, the agreement with Pandora measurements is degraded as localized polluted plumes observed by Pandora are spatially averaged over larger areas (aircraft-to-Pandora slope: TEMPO scale = 0.88; TROPOMI scale = 0.77; OMI scale = 0.57). This behavior suggests that satellite products are representative of individual Pandora observations up to a certain pollution scale that depends on satellite spatial resolution. In these two regions, Pandora and TEMPO or TROPOMI have the potential to compare well up to pollution scales of 30 x 1015 molecules cm-2. Two publicly available OMI tropospheric NO2 retrievals are both found to be biased low with respect to Pandora observations (NASA V3 Standard Product slope = 0.18 and Berkeley High Resolution Product slope = 0.30). However, the agreement improves when higher resolution a priori inputs are used for the tropospheric air mass factor calculation. Overall, this work explores best practices for satellite validation strategies by showing the sensitivity to product spatial resolution and demonstrates how the high spatial resolution NO2 data retrieved from airborne spectrometers, such as GeoTASO, can be used with high temporal resolution surface observations to evaluate the influence of spatial heterogeneity on validation results. [ABSTRACT FROM AUTHOR]

Published

2019

20. Nitrogen dioxide and formaldehyde measurements from the GEOstationary Coastal and Air Pollution Events (GEO-CAPE) Airborne Simulator over Houston, Texas.

Author

Nowlan, Caroline R., Liu, Xiong, Janz, Scott J., Kowalewski, Matthew G., Chance, Kelly, Follette-Cook, Melanie B., Fried, Alan, González Abad, Gonzalo, Herman, Jay R., Judd, Laura M., Kwon, Hyeong-Ahn, Loughner, Christopher P., Pickering, Kenneth E., Richter, Dirk, Spinei, Elena, Walega, James, Weibring, Petter, and Weinheimer, Andrew J.

Subjects

ATMOSPHERIC nitrogen dioxide, GEOSTATIONARY satellites, AIR pollution, FORMALDEHYDE & the environment, COASTS

Abstract

The GEOstationary Coastal and Air Pollution Events (GEO-CAPE) Airborne Simulator (GCAS) was developed in support of NASA's decadal survey GEO-CAPE geostationary satellite mission. GCAS is an airborne push-broom remote-sensing instrument, consisting of two channels which make hyperspectral measurements in the ultraviolet/visible (optimized for air quality observations) and the visible–near infrared (optimized for ocean color observations). The GCAS instrument participated in its first intensive field campaign during the Deriving Information on Surface Conditions from Column and Vertically Resolved Observations Relevant to Air Quality (DISCOVER-AQ) campaign in Texas in September 2013. During this campaign, the instrument flew on a King Air B-200 aircraft during 21 flights on 11 days to make air quality observations over Houston, Texas. We present GCAS trace gas retrievals of nitrogen dioxide (NO2) and formaldehyde (CH2O), and compare these results with trace gas columns derived from coincident in situ profile measurements of NO2 and CH2O made by instruments on a P-3B aircraft, and with NO2 observations from ground-based Pandora spectrometers operating in direct-sun and scattered light modes. GCAS tropospheric column measurements correlate well spatially and temporally with columns estimated from the P-3B measurements for both NO2 (r2=0.89) and CH2O (r2=0.54) and with Pandora direct-sun (r2=0.85) and scattered light (r2=0.94) observed NO2 columns. Coincident GCAS columns agree in magnitude with NO2 and CH2O P-3B-observed columns to within 10 % but are larger than scattered light Pandora tropospheric NO2 columns by 33 % and direct-sun Pandora NO2 columns by 50 %. [ABSTRACT FROM AUTHOR]

Published

2018

21. First Top‐Down Estimates of Anthropogenic NO<italic>x</italic> Emissions Using High‐Resolution Airborne Remote Sensing Observations.

Author

Souri, Amir H., Choi, Yunsoo, Pan, Shuai, Curci, Gabriele, Nowlan, Caroline R., Janz, Scott J., Kowalewski, Matthew G., Liu, Junjie, Herman, Jay R., and Weinheimer, Andrew J.

Abstract

Abstract: A number of satellite‐based instruments have become an essential part of monitoring emissions. Despite sound theoretical inversion techniques, the insufficient samples and the footprint size of current observations have introduced an obstacle to narrow the inversion window for regional models. These key limitations can be partially resolved by a set of modest high‐quality measurements from airborne remote sensing. This study illustrates the feasibility of nitrogen dioxide (NO2) columns from the Geostationary Coastal and Air Pollution Events Airborne Simulator (GCAS) to constrain anthropogenic NOx emissions in the Houston‐Galveston‐Brazoria area. We convert slant column densities to vertical columns using a radiative transfer model with (i) NO2 profiles from a high‐resolution regional model (1 × 1 km2) constrained by P‐3B aircraft measurements, (ii) the consideration of aerosol optical thickness impacts on radiance at NO2 absorption line, and (iii) high‐resolution surface albedo constrained by ground‐based spectrometers. We characterize errors in the GCAS NO2 columns by comparing them to Pandora measurements and find a striking correlation (r > 0.74) with an uncertainty of 3.5 × 1015 molecules cm−2. On 9 of 10 total days, the constrained anthropogenic emissions by a Kalman filter yield an overall 2–50% reduction in polluted areas, partly counterbalancing the well‐documented positive bias of the model. The inversion, however, boosts emissions by 94% in the same areas on a day when an unprecedented local emissions event potentially occurred, significantly mitigating the bias of the model. The capability of GCAS at detecting such an event ensures the significance of forthcoming geostationary satellites for timely estimates of top‐down emissions. [ABSTRACT FROM AUTHOR]

Published

2018

22. Atmospheric Correction of Hyperspectral GCAS Airborne Measurements Over the North Atlantic Ocean and Louisiana Shelf.

Author

Minwei Zhang, Chuanmin Hu, Kowalewski, Matthew G., and Janz, Scott J.

Subjects

HYPERSPECTRAL imaging systems, MODIS (Spectroradiometer), OCEAN color measurement, SCATTERING (Physics)

Abstract

The Geostationary Coastal and Air Pollution Events Airborne Simulator (GCAS) instrument has been used as a precursor for a hyperspectral instrument on the future geostationary satellite, yet its ability to "measure" ocean reflectance needs to be evaluated. Here, we demonstrate its capacity through vicarious calibration and atmospheric correction of data collected during flight campaigns over the Louisiana shelf in September 2013 and over the North Atlantic Ocean in November 2015. GCAS-measured at-sensor radiance was first vicariously calibrated using concurrent measurements by the Moderate Resolution Imaging Spectrometer (MODIS) and radiative transfer simulations with the MODerate resolution atmospheric TRANsmission (MODTRAN). Then, atmospheric correction has been implemented using MODTRAN-developed lookup tables and the traditional Gordon and Wang "black pixel" approach but with nonzero water-leaving radiance in the near-infrared accounted for through iteration. The atmospheric correction algorithm was applied to the vicariously calibrated GCAS imagery, with resulting Rrs compared with concurrent MODIS Rrs and in situ Rrs. The comparison shows a mean relative difference of about 25% (N = 11) between GCAS and in situ Rrs in the blue-green bands for clear to moderately turbid waters. [ABSTRACT FROM AUTHOR]

Published

2018

23. Atmospheric correction of hyperspectral airborne GCAS measurements over the Louisiana Shelf using a cloud shadow approach.

Author

Zhang, Minwei, Hu, Chuanmin, Kowalewski, Matthew G., Janz, Scott J., Lee, Zhongping, and Wei, Jianwei

Subjects

HYPERSPECTRAL imaging systems, CLOUD dynamics, ATMOSPHERIC radiation measurement, MODIS (Spectroradiometer), GEOSTATIONARY Operational Environmental Satellite (GOES)

Abstract

As an image-driven method to correct for atmospheric effects, the cloud shadow (CS) approach does not require accurate radiometric calibration of the sensor, making it feasible to process remotely sensed data when radiometric calibration may contain non-negligible uncertainties. Using measurements from the Geostationary Coastal and Air Pollution Events Airborne Simulator and from the Moderate Resolution Imaging Spectroradiometer over the Louisiana Shelf, we evaluate the CS approach to airplane measurements in turbid-water environments. The original CS approach somehow produced remote-sensing reflectance (Rrs, sr−1) with an abnormal spectral shape, likely a result of the assumption of identical path radiance for the pair of pixels in and out of the shadow, which is not exactly valid for measurements made from a low-altitude airplane. To overcome this limitation, an empirical scheme using an effective wavelength-dependent radiance reflectance for the cloud (γ, sr−1) was developed and reasonable GCAS Rrs retrievals are then generated, which were further validated against in situ Rrs. Issues and challenges in applying CS to measurements of low-altitude airplanes are discussed. [ABSTRACT FROM AUTHOR]

Published

2017

24. Remote sensing capabilities of the Airborne Compact Atmospheric Mapper.

Author

Kowalewski, Matthew G. and Janz, Scott J.

Published

2009

25. Development of a filter radiometer monitor system for integrating sphere sources.

Author

Ding, Leibo, Kowalewski, Matthew G., Cooper, John W., Smith, Gilbert R., and Butler, James J.

Published

2009

26. Calibration of a radiance standard for the NPP/OMPS instrument.

Author

Butler, James J., Janz, Scott J., Johnson, B. Carol, Saunders, Robert D., Cooper, John W., Kowalewski, Matthew G., and Barnes, Robert A.

Published

2008

27. The effect of polarization sensitivity of Brewer spectrometers on Direct Sun measurements.

Author

Cede, Alexander M., Labow, Gordon, Kowalewski, Matthew G., and Herman, Jay R.

Published

2004

28. Deriving aerosol parameters from absolute UV sky radiance measurements using a Brewer double spectrometer.

Author

Cede, Alexander M., Labow, Gordon, Kowalewski, Matthew G., Krotkov, Nickolay A., and Dubovik, Oleg

Published

2003

29. Polar mesospheric clouds (PMCs) observed by the Ozone Monitoring Instrument (OMI) on Aura.

Author

DeLand, Matthew T., Shettle, Eric P., Levelt, Pieternel F., and Kowalewski, Matthew G.

Published

2010

30. Detecting nitrogen oxide emissions in Qatar and quantifying emission factors of gas-fired power plants - A four-years study.

Author

Rey-Pommier, Anthony, Chevallier, Frédéric, Ciais, Philippe, Kushta, Jonilda, Christoudias, Theodoros, Bayram, I. Safak, and Sciare, Jean

Subjects

GAS power plants, AIR pollutants, POWER plants, NITROGEN oxides, ELECTRIC power production, GASES from plants, CEMENT plants, NITROGEN dioxide

Abstract

Nitrogen oxides (NOx = NO + NO2), produced in urban areas and industrial facilities (particularly in fossil fuel-fired power plants), are major sources of air pollutants, with implications for human health, leading local and national authorities to estimate their emissions using inventories. In Qatar, these inventories are not systematically updated, while the country is experiencing fast economic growth. Here, we use spaceborne retrievals of nitrogen dioxide (NO2) columns at high spatial resolution from the TROPOMI instrument to estimate NOx emissions in Qatar from 2019 to 2022 with a flux-divergence scheme, according to which emissions are calculated as the sum of a transport term and a sink term representing the three-body reaction comprising NO2 and hydroxyl radical (OH). Our results highlight emissions from gas power plants in the north-east of the country, and from the urban area of the capital Doha. The emissions from cement plants in the west and different industrial facilities in the south-east are under-estimated, due to frequent low-quality measurements of NO2 columns in these areas. Our top-down model estimates a weekly cycle with lower emissions on Fridays compared to the rest of the week, which is consistent with social norms in the country, and an annual cycle with mean emissions of 9.56 kt per month for the four-year period. These monthly emissions differ from CAMS-GLOB-ANT_v5.3 and EDGARv6.1 global inventories, for which the annual cycle is less marked and the average emissions are respectively 1.44 and 1.68 times higher. Our emission estimates are correlated with local electricity generation, and allow to infer a mean NOx emission factor of 0.557 tNOx.GWh−1 for the three gas power plants in the Ras Laffan area. [ABSTRACT FROM AUTHOR]

Published

2023