Global partitioning of NOx sources using satellite observations: Relative roles of fossil fuel combustion, biomass burning and soil emissions

Jaeglé, Lyatt; Steinberger, Linda; Martin, Randall V.; Chance, K.

doi:10.1039/b502128f

Cited by 414 publications

(457 citation statements)

References 65 publications

(88 reference statements)

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“…Soil NO x Jaeglé et al [43] have performed top-down (satellite) partitioning among NO x sources, including fuel combustion (fossil fuel and biofuel), biomass burning and soils. These are combined with bottom-up inventories to provide much improved a posteriori inventories of NO x sources and their relative importance.…”

Section: Science Studies Including Special Observationsmentioning

confidence: 99%

Tropospheric emissions: Monitoring of pollution (TEMPO)

Zoogman

Liu

Suleiman

et al. 2017

Journal of Quantitative Spectroscopy and Radiative Transfer

264

144

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Section: Science Studies Including Special Observationsmentioning

confidence: 99%

Tropospheric emissions: Monitoring of pollution (TEMPO)

Zoogman

Liu

Suleiman

et al. 2017

Journal of Quantitative Spectroscopy and Radiative Transfer

264

144

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“…But for most of the rural Southeast, observed NO 2 is lower at 1000 LT than at 1330 LT. We hypothesize that the opposite diurnal variation between the observed (0. emissions (dependent on soil temperature) are strongest in the afternoon [Ludwig et al, 2001], and there is evidence that these emissions are significantly underestimated in the model [Jaeglé et al, 2005]. Furthermore, Park et al [2007] found strong biomass burning activity throughout the Southeast and GEOS-Chem does not take into account the diurnal cycle of fires (see next section).…”

Section: Diurnal Variation In No 2 Columns Over Fossil Fuel Source Rementioning

confidence: 99%

“…Data sets of tropospheric NO 2 columns retrieved from the Global Ozone Monitoring Experiment (GOME), the Scanning Imaging Absorption Chartography (SCIAMACHY) and the Ozone Monitoring Experiment (OMI) now span more than 10 years (1996)(1997)(1998)(1999)(2000)(2001)(2002)(2003)(2004)(2005)(2006) and have been used for trend studies van der A et al, 2006a]. GOME and SCIAMACHY tropospheric NO 2 data has been used to estimate surface emissions of NO x [Martin et al, 2003;Jaeglé et al, 2004Jaeglé et al, , 2005Müller and Stavrakou, 2005;Bertram et al, 2005;Toenges-Schüller et al, 2006;Konovalov et al, 2006;Martin et al, 2006;Kim et al, 2006] and lightning NO x production [Boersma et al, 2005;Beirle et al, 2006;Martin et al, 2007].…”

Section: Introductionmentioning

confidence: 99%

Intercomparison of SCIAMACHY and OMI tropospheric NO₂ columns: Observing the diurnal evolution of chemistry and emissions from space

et al. 2008

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[1] Concurrent (August 2006) measurements of tropospheric NO 2 columns from OMI aboard Aura (1330 local overpass time) and SCIAMACHY aboard Envisat (1000 local overpass time) offer an opportunity to examine the consistency between the two instruments under tropospheric background conditions and the effect of different observing times. For scenes with tropospheric NO 2 columns <5.0 Â 10 15 molecules cm À2 , SCIAMACHY and OMI agree within 1.0-2.0 Â 10 15 molecules cm À2 , consistent with the detection limits of both instruments. We find evidence for a low bias of 0.2 Â 10 15 molecules cm À2 in OMI observations over remote oceans. Over the fossil fuel source regions at northern midlatitudes, we find that SCIAMACHY observes up to 40% higher NO 2 at 1000 local time (LT) than OMI at 1330 LT. Over biomass burning regions in the tropics, SCIAMACHY observes up to 40% lower NO 2 columns than OMI. These differences are present in the spectral fitting of the data (slant column) and are augmented in the fossil fuel regions and dampened in the tropical biomass burning regions by the expected increase in air mass factor as the mixing depth rises from 1000 to 1330 LT. Using a global 3-D chemical transport model (GEOS-Chem), we show that the 1000-1330 LT decrease in tropospheric NO 2 column over fossil fuel source regions can be explained by photochemical loss, dampened by the diurnal cycle of anthropogenic emissions that has a broad daytime maximum. The observed 1000-1330 LT NO 2 column increase over tropical biomass burning regions points to a sharp midday peak in emissions and is consistent with a diurnal cycle of emissions derived from geostationary satellite fire counts.

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“…These data have been useful for understanding global (e.g., Martin et al, 2003;Jaegl et al, 2005), regional (e.g., Duncan et al, 2016;Travis et al, 2016) and local air quality (e.g., Zhu et al, 2017) over daily (e.g., Valin et al, 2014;de Foy et al, 2016), seasonal (e.g., Russell et al, 2010), interannual, and decadal time periods (van der et al, 2008;De Smedt et al, 2015). However, the relatively coarse spatial resolutions and single daily observation times have substantially limited these applications, particularly within the air quality management community which needs to be able to distinguish temporal profiles of emissions from different source sectors and identify specific physical processes to justify regulatory decisions.…”

Section: Introductionmentioning

confidence: 99%

The Dawn of Geostationary Air Quality Monitoring: Case Studies From Seoul and Los Angeles

Judd

Al-Saadi

Valin

et al. 2018

Front. Environ. Sci.

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With the near-future launch of geostationary Earth orbit (GEO) pollution monitoring satellite instruments over North America, East Asia, and Europe, the air quality community is preparing for an integrated global atmospheric composition observing system at unprecedented spatial and temporal resolutions. One of the ways that NASA has supported this community preparation is through demonstration of future space-borne capabilities using the Geostationary Trace gas and Aerosol Sensor Optimization (GeoTASO) airborne instrument. This paper integrates repeated high-resolution NO 2 maps from GeoTASO, ground-based Pandora spectrometers data, and low Earth orbit (LEO) measurements from the Ozone Mapping and Profiler Suite, for case studies over two regions: the Seoul Metropolitan Area, South Korea on June 9th, 2016 and Los Angeles Basin, California on June 27th, 2017. This dataset provides a unique opportunity to illustrate how GEO air quality monitoring platforms and ground-based remote sensing networks will close the current spatiotemporal observation gap. In both areas, the earliest morning maps exhibit spatial patterns similar to emission source areas (e.g., urbanized valleys, roadways, major airports) and change later in the day due to boundary layer dynamics, transport, and/or chemistry. On June 9th, 2016, GeoTASO observes NO 2 accumulating within the Seoul Metropolitan Area, while NO 2 peaks in the morning and decreases throughout the afternoon in the Los Angeles Basin on June 27th, 2017. The nominal resolution of GeoTASO is finer than will be obtained from GEO platforms, but when NO 2 data over Los Angeles are up-scaled to the expected resolution of TEMPO, spatial features discussed are preserved. Pandora instruments installed in both metropolitan areas capture the diurnal patterns observed by GeoTASO, continuously and over longer time periods and will play a critical role in validation of the next generation of satellite measurements. These case studies demonstrate the diversity of diurnal patterns in two urbanized regions and associates them with meteorology Judd et al.Dawn of Geostationary Air Quality Monitoring or anthropogenic patterns, hinting at the spatial and temporal richness of the upcoming GEO observations. LEO measurements, despite their inability to capture the diurnal patterns at fine spatial resolution, will be essential for intercalibrating the GEO radiances and cross-validating the GEO retrievals in an integrated global observing system.

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Global partitioning of NOx sources using satellite observations: Relative roles of fossil fuel combustion, biomass burning and soil emissions

Cited by 414 publications

References 65 publications

Tropospheric emissions: Monitoring of pollution (TEMPO)

Tropospheric emissions: Monitoring of pollution (TEMPO)

Intercomparison of SCIAMACHY and OMI tropospheric NO₂ columns: Observing the diurnal evolution of chemistry and emissions from space

The Dawn of Geostationary Air Quality Monitoring: Case Studies From Seoul and Los Angeles

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Global partitioning of NOx sources using satellite observations: Relative roles of fossil fuel combustion, biomass burning and soil emissions

Cited by 414 publications

References 65 publications

Tropospheric emissions: Monitoring of pollution (TEMPO)

Tropospheric emissions: Monitoring of pollution (TEMPO)

Intercomparison of SCIAMACHY and OMI tropospheric NO2 columns: Observing the diurnal evolution of chemistry and emissions from space

The Dawn of Geostationary Air Quality Monitoring: Case Studies From Seoul and Los Angeles

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Intercomparison of SCIAMACHY and OMI tropospheric NO₂ columns: Observing the diurnal evolution of chemistry and emissions from space