Demonstration of an Ethane Spectrometer for Methane Source Identification

Yacovitch, Tara I.; Herndon, S. C.; Roscioli, Joseph R.; Floerchinger, Cody; McGovern, Ryan M.; Agnese, M.; Pétron, Gabrielle; Kofler, J.; Sweeney, Colm; Karion, A.; Conley, Stephen; Kort, E. A.; Nähle, Lars; Fischer, M.; Hildebrandt, Lars; Koeth, Johannes; McManus, J. Barry; Nelson, David D.; Zahniser, M. S.; Kolb, C. E.

doi:10.1021/es501475q

Cited by 111 publications

(143 citation statements)

References 34 publications

(39 reference statements)

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“…The IHG is calculated from the difference of Zugspitze and Lauder monthly mean time series, assuming that Zugspitze (Lauder) observations are representative of the northern (southern) high-latitude XCH 4 and XC 2 H 6 average. This assumption is supported by the following argumentation: ethane is approximately well-mixed in high northern and southern latitudes (Aydin et al, 2011) as its lifetime of 2.6 months (Xiao et al, 2008) exceeds zonal mixing timescales of about 2 weeks (Williams and Koppmann, 2007). Methane has an even longer lifetime of about 9 years (Prather et al, 2012) and is therefore well-mixed north of 30 • N and in the Southern Hemisphere (Simpson et al, 2002;Saito et al, 2012).…”

Section: Results Of Long-term Trend Analysismentioning

confidence: 96%

“…Major ethane sources are biomass burning, biofuel use, and fossil fuel fugitive emissions from the production and transport of coal (coal-bed gas), oil (associated gas), and natural gas (unassociated gas). About 80 % of global ethane emissions are located in the Northern Hemisphere (Xiao et al, 2008). In contrast to methane, ethane cannot completely mix over both hemispheres, as its lifetime is short compared to the interhemispheric exchange time of approximately 1 year (Tans, 1997;Williams and Koppmann, 2007;Aydin et al, 2011).…”

Section: Results Of Long-term Trend Analysismentioning

confidence: 99%

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Contribution of oil and natural gas production to renewed increase in atmospheric methane (2007–2014): top–down estimate from ethane and methane column observations

2016

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Abstract. Harmonized time series of column-averaged mole fractions of atmospheric methane and ethane over the period 1999-2014 are derived from solar Fourier transform infrared (FTIR) measurements at the Zugspitze summit (47 • N, 11 • E; 2964 m a.s.l.) and at Lauder (45 • S, 170 • E; 370 m a.s.l.). Long-term trend analysis reveals a consistent renewed methane increase since 2007 of 6. 2 [5.6, 6.9] ppb yr −1 (parts-per-billion per year) at the Zugspitze and 6.0 [5.3, 6.7] ppb yr −1 at Lauder (95 % confidence intervals). Several recent studies provide pieces of evidence that the renewed methane increase is most likely driven by two main factors: (i) increased methane emissions from tropical wetlands, followed by (ii) increased thermogenic methane emissions due to growing oil and natural gas production. Here, we quantify the magnitude of the second class of sources, using long-term measurements of atmospheric ethane as a tracer for thermogenic methane emissions. and can be assigned to thermogenic methane emissions with an ethane-to-methane ratio (EMR) of 12-19 %. We present optimized emission scenarios for 2007-2014 derived from an atmospheric two-box model. From our trend observations we infer a total ethane emission increase over the period 2007-2014 from oil and natural gas sources of 1-11 Tg yr −1 along with an overall methane emission increase of 24-45 Tg yr −1 . Based on these results, the oil and natural gas emission contribution (C) to the renewed methane increase is deduced using three different emission scenarios with dedicated EMR ranges. Reference scenario 1 assumes an oil and gas emission combination with EMR = 7.0-16.2 %, which results in a minimum contribution C > 39 % (given as lower bound of 95 % confidence interval). Beside this most plausible scenario 1, we consider two less realistic limiting cases of pure oil-related emissions (scenario 2 with EMR = 16.2-31.4 %) and pure natural gas sources (scenario 3 with EMR = 4.4-7.0 %), which result in C > 18 % and C > 73 %, respectively. Our results suggest that long-term observations of columnaveraged ethane provide a valuable constraint on the source attribution of methane emission changes and provide basic knowledge for developing effective climate change mitigation strategies.

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Section: Results Of Long-term Trend Analysismentioning

confidence: 96%

Section: Results Of Long-term Trend Analysismentioning

confidence: 99%

Contribution of oil and natural gas production to renewed increase in atmospheric methane (2007–2014): top–down estimate from ethane and methane column observations

2016

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“…Ethane is a significant component of NG, whereas microbial CH 4 sources, such as landfills, sewage, and wetlands, produce little or no C 2 H 6 (15). Because Boston has no geologic CH 4 seeps, no oil and gas production or refining, and low rates of biomass burning, there are no known significant sources of C 2 H 6 in the region other than NG.…”

Section: Contribution Of Ng To Elevated Ch 4 Concentrationsmentioning

confidence: 99%

Methane emissions from natural gas infrastructure and use in the urban region of Boston, Massachusetts

McKain

Down

Raciti

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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262

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Methane emissions from natural gas delivery and end use must be quantified to evaluate the environmental impacts of natural gas and to develop and assess the efficacy of emission reduction strategies. We report natural gas emission rates for 1 y in the urban region of Boston, using a comprehensive atmospheric measurement and modeling framework. Continuous methane observations from four stations are combined with a high-resolution transport model to quantify the regional average emission flux, 18.5 ± 3.7 (95% confidence interval) g CH 4 ·m −2 ·y −1 . Simultaneous observations of atmospheric ethane, compared with the ethane-to-methane ratio in the pipeline gas delivered to the region, demonstrate that natural gas accounted for ∼60-100% of methane emissions, depending on season. Using government statistics and geospatial data on natural gas use, we find the average fractional loss rate to the atmosphere from all downstream components of the natural gas system, including transmission, distribution, and end use, was 2.7 ± 0.6% in the Boston urban region, with little seasonal variability. This fraction is notably higher than the 1.1% implied by the most closely comparable emission inventory.natural gas distribution | greenhouse gas emissions | cities | methane A tmospheric methane (CH 4 ) is an important greenhouse gas (1) and major contributor to elevated surface ozone concentrations worldwide (2). Current atmospheric CH 4 concentrations are 2.5 times greater than preindustrial levels due to anthropogenic emissions from both biological and fossil fuel sources. The growth rate of CH 4 in the atmosphere slowed beginning in the mid-1980s and plateaued in the mid-2000s, but growth has resumed since 2007. The factors responsible for the observed global increase and interannual trends, and the spatiotemporal distribution of sources, remain uncertain (3).Losses of natural gas (NG) to the atmosphere are a significant component of anthropogenic CH 4 emissions (3), with important implications for resource use efficiency, worker and public safety, air pollution, and human health (4), and for the climate impact of NG as a large and growing source of energy. A major focus area of the US Climate Action Plan is reduction of CH 4 emissions (5), but implementation requires identification of dominant source types, locations, and magnitudes. A recent review and synthesis of CH 4 emission measurements in North America, spanning scales of individual components to the continent, found that inventory methods consistently underestimate CH 4 emissions, that fossil fuels are likely responsible for a large portion of the underestimate, and that significant fugitive emissions may be occurring from all segments of the NG system (6).The present study quantifies CH 4 fluxes from NG in the urbanized region centered on Boston. Elevated CH 4 concentrations in urban environments have been documented around the world for decades (7) (SI Appendix, Table S1) and attributed to a variety of anthropogenic source types. Recent studies of urbanized regions in...

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“…McKain et al (2015), for example, measure CH 4 and ethane at several sites in Boston, and they use CH 4 / ethane ratios reported from natural gas pipeline operators to estimate the portion of Boston's CH 4 emissions that are due to natural gas leaks. Several other studies similarly use ethane measurements to explore oil and gas industry emissions from Los Angeles (Wennberg et al, 2012), Dallas, Texas (Yacovitch et al, 2014), the Barnett Shale region Townsend-Small et al, 2015), and from global oil and gas operations (e.g., Simpson et al, 2012;Schwietzke et al, 2014).…”

Section: Ethanementioning

confidence: 99%

“…All data in this figure are from the USGS Geochemistry Laboratory Database (USGS Energy Resources Program, 2015). mentation has also become more widely available with Aerodyne, Inc.'s ethane analyzer (Yacovitch et al, 2014).…”

Section: Ethanementioning

confidence: 99%

Constraining sector-specific CO<sub>2</sub> and CH<sub>4</sub> emissions in the US

Miller

Michalak

2017

Atmos. Chem. Phys.

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Abstract. This review paper explores recent efforts to estimate state-and national-scale carbon dioxide (CO 2 ) and methane (CH 4 ) emissions from individual anthropogenic source sectors in the US. Nearly all state and national climate change regulations in the US target specific source sectors, and detailed monitoring of individual sectors presents a greater challenge than monitoring total emissions. We particularly focus on opportunities to synthesize disparate types of information on emissions, including emission inventory data and atmospheric greenhouse gas data.We find that inventory estimates of sector-specific CO 2 emissions are sufficiently accurate for policy evaluation at the national scale but that uncertainties increase at state and local levels. CH 4 emission inventories are highly uncertain for all source sectors at all spatial scales, in part because of the complex, spatially variable relationships between economic activity and CH 4 emissions. In contrast to inventory estimates, top-down estimates use measurements of atmospheric mixing ratios to infer emissions at the surface; thus far, these efforts have had some success identifying urban CO 2 emissions and have successfully identified sector-specific CH 4 emissions in several opportunistic cases. We also describe a number of forward-looking opportunities that would aid efforts to estimate sector-specific emissions: fully combine existing top-down datasets, expand intensive aircraft measurement campaigns and measurements of secondary tracers, and improve the economic and demographic data (e.g., activity data) that drive emission inventories. These steps would better synthesize inventory and topdown data to support sector-specific emission reduction policies.

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Demonstration of an Ethane Spectrometer for Methane Source Identification

Cited by 111 publications

References 34 publications

Contribution of oil and natural gas production to renewed increase in atmospheric methane (2007–2014): top–down estimate from ethane and methane column observations

Contribution of oil and natural gas production to renewed increase in atmospheric methane (2007–2014): top–down estimate from ethane and methane column observations

Methane emissions from natural gas infrastructure and use in the urban region of Boston, Massachusetts

Constraining sector-specific CO<sub>2</sub> and CH<sub>4</sub> emissions in the US

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Demonstration of an Ethane Spectrometer for Methane Source Identification

Cited by 111 publications

References 34 publications

Contribution of oil and natural gas production to renewed increase in atmospheric methane (2007–2014): top–down estimate from ethane and methane column observations

Contribution of oil and natural gas production to renewed increase in atmospheric methane (2007–2014): top–down estimate from ethane and methane column observations

Methane emissions from natural gas infrastructure and use in the urban region of Boston, Massachusetts

Constraining sector-specific CO&lt;sub&gt;2&lt;/sub&gt; and CH&lt;sub&gt;4&lt;/sub&gt; emissions in the US

Contact Info

Product

Resources

About

Constraining sector-specific CO<sub>2</sub> and CH<sub>4</sub> emissions in the US