Assessing the optimized precision of the aircraft mass balance method for measurement of urban greenhouse gas emission rates through averaging

Heimburger, A. M. F.; Harvey, Rebecca M.; Shepson, P. B.; Stirm, B. H.; Gore, Chloe; Turnbull, J. C.; Cambaliza, Maria Obiminda; Salmon, O. E.; Kerlo, Anna-Elodie; Lavoie, T. N.; Davis, Kenneth J.; Lauvaux, Thomas; Karion, A.; Sweeney, Colm; Brewer, W. Alan; Hardesty, R. Michael; Gurney, K. R.

doi:10.1525/elementa.134

Cited by 61 publications

(91 citation statements)

References 52 publications

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“…We show that NO x and CO emission rates from X/CO 2 × Vulcan CO 2 are consistent with the D.C.‐Balt NO x and CO emission rates calculated using the mass balance approach (section 2.7). We conduct a similar exercise with the Indianapolis Winter 2014 CO/CO 2 enhancement ratio reported in this study and the Hestia Indianapolis CO 2 emission rate and see agreement with the mass balance CO emission rate reported from the area by Heimburger et al (). The results of the exercise are provided in Table .…”

Section: Resultssupporting

confidence: 83%

“…Figure also shows CO/CO 2 enhancement ratios observed by the UMD aircraft in D.C.‐Balt for the year after WINTER (February 2016), as well as CO/CO 2 enhancement ratios observed by the Purdue aircraft during a 3‐week observations period in Indianapolis in November–December 2014 (Heimburger et al, ). This is a useful comparison, since mobile sources (on‐road + nonroad) account for 77% (Table ) and 93% of D.C.‐Balt and Indianapolis CO emissions during the measurement months (EPA, ), respectively, and we expect the D.C.‐Balt and Indianapolis mobile fleets to be comparable.…”

Section: Resultsmentioning

confidence: 94%

“…The Purdue aircraft was used to conduct measurements in Indianapolis in November to December 2014. Methods for the Indianapolis measurements are discussed by Heimburger et al ().…”

Section: Methods and Datamentioning

confidence: 99%

“…The flux values calculated at each downwind sampling point, F C , i , are interpolated/extrapolated to create a two‐dimensional x ‐ z plane, or matrix ( M C ) of downwind CO or NO y * fluxes (Heimburger et al, ). The matrix extends from the surface to the top of the boundary layer and only extends horizontally to include urban‐influenced air (section 2.5).…”

Section: Methods and Datamentioning

confidence: 99%

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Top‐Down Estimates of NO_x and CO Emissions From Washington, D.C.‐Baltimore During the WINTER Campaign

et al. 2018

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Airborne mass balance experiments were conducted around the Washington, D.C.‐Baltimore area using research aircraft from Purdue University and the University of Maryland to quantify emissions of nitrogen oxides (NOx = NO + NO2) and carbon monoxide (CO). The airborne mass balance experiments supported the Wintertime INvestigation of Transport, Emissions, and Reactivity (WINTER) campaign, an intensive airborne study of anthropogenic emissions along the Northeastern United States in February–March 2015, and the Fluxes of Atmospheric Greenhouse Gases in Maryland project which seeks to provide best estimates of anthropogenic emissions from the Washington, D.C.‐Baltimore area. Top‐down emission rates of NOx and CO estimated from the mass balance flights are compared with the Environmental Protection Agency's 2011 and 2014 National Emissions Inventory (NEI‐11 and NEI‐14). Inventory and observation‐derived NOx emission rates are consistent within the measurement uncertainty. Observed CO emission rates are a factor of 2 lower than reported by the NEI. The NEI's accuracy has been evaluated for decades by studies of anthropogenic emissions, yet despite continuous inventory updates, observation‐inventory discrepancies persist. WINTER NOx/CO2 enhancement ratios are consistent with inventories, but WINTER CO/NOx and CO/CO2 enhancement ratios are lower than those reported by other urban summertime studies, suggesting a strong influence of CO seasonal trends and/or nationwide CO reductions. There is a need for reliable observation‐based criterion pollutant emission rate measurements independent of the NEI. Such determinations could be supplied by the community's reporting of sector‐specific criteria pollutant/CO2 enhancement ratios and subsequent multiplication with currently available and forthcoming high‐resolution CO2 inventories.

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Section: Resultssupporting

confidence: 83%

Section: Resultsmentioning

confidence: 94%

“…The Purdue aircraft was used to conduct measurements in Indianapolis in November to December 2014. Methods for the Indianapolis measurements are discussed by Heimburger et al ().…”

Section: Methods and Datamentioning

confidence: 99%

Section: Methods and Datamentioning

confidence: 99%

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Top‐Down Estimates of NO_x and CO Emissions From Washington, D.C.‐Baltimore During the WINTER Campaign

et al. 2018

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“…Uncertainties, dominated by the stochastic nature of turbulence, typically range from 20 to 80 % for horizontal averaging scales of 1-30 km but can exceed 100 % when fluxes are small. Similar error ranges are reported for other surface exchange quantification methods (Cambaliza et al, 2014;Chang et al, 2014;Heimburger et al, 2017).…”

Section: Introductionsupporting

confidence: 83%

The NASA Carbon Airborne Flux Experiment (CARAFE): instrumentation and methodology

et al. 2018

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Abstract. The exchange of trace gases between the Earth's surface and atmosphere strongly influences atmospheric composition. Airborne eddy covariance can quantify surface fluxes at local to regional scales (1-1000 km), potentially helping to bridge gaps between top-down and bottomup flux estimates and offering novel insights into biophysical and biogeochemical processes. The NASA Carbon Airborne Flux Experiment (CARAFE) utilizes the NASA C-23 Sherpa aircraft with a suite of commercial and custom instrumentation to acquire fluxes of carbon dioxide, methane, sensible heat, and latent heat at high spatial resolution. Key components of the CARAFE payload are described, including the meteorological, greenhouse gas, water vapor, and surface imaging systems. Continuous wavelet transforms deliver spatially resolved fluxes along aircraft flight tracks. Flux analysis methodology is discussed in depth, with special emphasis on quantification of uncertainties. Typical uncertainties in derived surface fluxes are 40-90 % for a nominal resolution of 2 km or 16-35 % when averaged over a full leg (typically 30-40 km). CARAFE has successfully flown two missions in the eastern US in 2016 and 2017, quantifying fluxes over forest, cropland, wetlands, and water. Preliminary results from these campaigns are presented to highlight the performance of this system.

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Urban emissions of water vapor in winter

et al. 2017

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Elevated water vapor (H2Ov) mole fractions were occasionally observed downwind of Indianapolis, IN, and the Washington, D.C.‐Baltimore, MD, area during airborne mass balance experiments conducted during winter months between 2012 and 2015. On days when an urban H2Ov excess signal was observed, H2Ov emission estimates range between 1.6 × 104 and 1.7 × 105 kg s−1 and account for up to 8.4% of the total (background + urban excess) advected flow of atmospheric boundary layer H2Ov from the urban study sites. Estimates of H2Ov emissions from combustion sources and electricity generation facility cooling towers are 1–2 orders of magnitude smaller than the urban H2Ov emission rates estimated from observations. Instances of urban H2Ov enhancement could be a result of differences in snowmelt and evaporation rates within the urban area, due in part to larger wintertime anthropogenic heat flux and land cover differences, relative to surrounding rural areas. More study is needed to understand why the urban H2Ov excess signal is observed on some days, and not others. Radiative transfer modeling indicates that the observed urban enhancements in H2Ov and other greenhouse gas mole fractions contribute only 0.1°C d−1 to the urban heat island at the surface. This integrated warming through the boundary layer is offset by longwave cooling by H2Ov at the top of the boundary layer. While the radiative impacts of urban H2Ov emissions do not meaningfully influence urban heat island intensity, urban H2Ov emissions may have the potential to alter downwind aerosol and cloud properties.

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Assessing the optimized precision of the aircraft mass balance method for measurement of urban greenhouse gas emission rates through averaging

Cited by 61 publications

References 52 publications

Top‐Down Estimates of NO_x and CO Emissions From Washington, D.C.‐Baltimore During the WINTER Campaign

Top‐Down Estimates of NO_x and CO Emissions From Washington, D.C.‐Baltimore During the WINTER Campaign

The NASA Carbon Airborne Flux Experiment (CARAFE): instrumentation and methodology

Urban emissions of water vapor in winter

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Assessing the optimized precision of the aircraft mass balance method for measurement of urban greenhouse gas emission rates through averaging

Cited by 61 publications

References 52 publications

Top‐Down Estimates of NOx and CO Emissions From Washington, D.C.‐Baltimore During the WINTER Campaign

Top‐Down Estimates of NOx and CO Emissions From Washington, D.C.‐Baltimore During the WINTER Campaign

The NASA Carbon Airborne Flux Experiment (CARAFE): instrumentation and methodology

Urban emissions of water vapor in winter

Contact Info

Product

Resources

About

Top‐Down Estimates of NO_x and CO Emissions From Washington, D.C.‐Baltimore During the WINTER Campaign

Top‐Down Estimates of NO_x and CO Emissions From Washington, D.C.‐Baltimore During the WINTER Campaign