Evaluating methane emission quantification performance and uncertainty of aerial technologies via high-volume single-blind controlled releases

Rutherford, Jeff; Sherwin, Evan D.; Chen, Yuanlei; Aminfard, Sam; Brandt, Adam R.

doi:10.31223/x5kq0x

Cited by 13 publications

(30 citation statements)

References 26 publications

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“…While not included in the present study, Bridger Photonics' Gas Mapping LiDAR has been independently tested elsewhere in single-blind and location-blind studies. 3,14,19 This study fills important gaps in previous literature. In particular, this is the first independent single-blind test of Scientific Aviation and MethaneAIR (Chulakadabba et al, 2023 18 used a collaborative technology validation experimental design in which the MethaneAIR team had editorial control over the publication of their results, with input from Stanford).…”

Section: Introductionmentioning

confidence: 73%

“…13 While detection capabilities vary by platform and technological approach, under ideal measurement conditions, aircraft can detect emissions below 100 kg (CH 4 )/h, and in some cases, below 10 kg (CH 4 )/h. 3,14,15 In contrast, most wide-area satellite have a detection limit around 1,000−1,500 kg(CH 4 )/ h, although targeted systems such as the GHGSat satellite and Maxar's WorldView-3 have detected emissions under, ideal conditions, as low as 200 and 30 kg(CH 4 )/h, respectively. 16,17 As companies and governments increasingly rely on aircraft methane management, accurately assessing these technologies' capabilities becomes increasingly important.…”

Section: Introductionmentioning

confidence: 99%

“…Top anthropogenic methane sources and targets for emissions reductions are the oil and gas sector, waste management, and agriculture . Conventional methods for detecting and quantifying methane emissions are time and labor intensive, with limited scalability due to reliance on individual site visits with methane detectors or optical gas imaging infrared cameras . Greenhouse gas inventories continue to use a so-called “bottom-up” method for estimating emissions, which underestimate emissions from the oil and gas sector compared to results from measurement surveys .…”

Section: Introductionmentioning

confidence: 99%

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Technological Maturity of Aircraft-Based Methane Sensing for Greenhouse Gas Mitigation

El Abbadi,

Chen,

Burdeau

et al. 2024

Environ. Sci. Technol.

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Methane is a major contributor to anthropogenic greenhouse gas emissions. Identifying large sources of methane, particularly from the oil and gas sectors, will be essential for mitigating climate change. Aircraft-based methane sensing platforms can rapidly detect and quantify methane point-source emissions across large geographic regions, and play an increasingly important role in industrial methane management and greenhouse gas inventory. We independently evaluate the performance of five major methane-sensing aircraft platforms: Carbon Mapper, GHGSat-AV, Insight M, MethaneAIR, and Scientific Aviation. Over a 6 week period, we released metered gas for over 700 singleblind measurements across all five platforms to evaluate their ability to detect and quantify emissions that range from 1 to over 1,500 kg(CH 4 )/h. Aircraft consistently quantified releases above 10 kg(CH 4 )/h, and GHGSat-AV and Insight M detected emissions below 5 kg(CH 4 )/h. Fully blinded quantification estimates for platforms using downward-facing imaging spectrometers have parity slopes ranging from 0.76 to 1.13, with R 2 values of 0.61 to 0.93; the platform using continuous air sampling has a parity slope of 0.5 (R 2 = 0.93). Results demonstrate that aircraft-based methane sensing has matured since previous studies and is ready for an increasingly important role in environmental policy and regulation.

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Section: Introductionmentioning

confidence: 73%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Technological Maturity of Aircraft-Based Methane Sensing for Greenhouse Gas Mitigation

El Abbadi,

Chen,

Burdeau

et al. 2024

Environ. Sci. Technol.

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“…The uncertainty bounds are generated by assuming ±25% errors of the mix ratio length minimum threshold α l , fetch radius r c and wind speed U 10 . We use ordinary least squares regression to assess quantification accuracy (Rutherford et al., 2023; Sherwin et al., 2023). The scenario with r s = 300 m demonstrates the best performance (Figure 1).…”

Section: Resultsmentioning

confidence: 99%

Measuring Carbon Dioxide Emissions From Liquefied Natural Gas (LNG) Terminals With Imaging Spectroscopy

Zhang,

Cusworth,

Ayasse

et al. 2023

Geophysical Research Letters

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The rapid growth of liquefied natural gas (LNG) exports underscores the importance of CO2 monitoring for LNG export terminals. We present a method for measuring LNG terminal CO2 emissions using remote sensing imaging spectroscopy. The method is first validated using 47 power plant emission events with in situ measured data, then applied to 22 emission events in Sabine Pass and Cameron. The power plant data set shows a robust correlation between our estimates and in situ data, with R2 0.9146 and the average error −2%. At Sabine Pass, eight point sources are identified with emission rates from 219.69 ± 54.95 to 1,083.22 ± 308.06 t/hr. At Cameron, three point sources are identified with emission rates from 91.64 ± 25.81 to 265.61 ± 67.80 t/hr. The liquefaction carbon intensity estimates also align with past study ranges. This illustrates that remote sensing can validate environmental reporting and CO2 inventories for industrial facilities.

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“…Four snapshot measurement technologies were used for the baseline measurements: an optical gas imaging (OGI) camera paired with a Hi-flow sampler that encompasses the entire emission source, a drone-based mass balance technology provided by SeekOps Inc. (“SeekOps”), an aerial LiDAR plume identification system provided by Bridger Photonics (“Bridger”), and satellite measurements provided by GHGSat. All four technologies have undergone controlled tests and field trials, with the results made public in peer-reviewed studies. − During the 6 month enhanced monitoring phase, operators conducted weekly audio, visual, and olfactory (AVO) inspections and monthly leak detection and repair (LDAR) surveys using either OGI cameras or Bridger measurements. Additionally, operators submitted monthly bottom-up inventories and installed CMS on some or all of their enrolled sites during this phase.…”

Section: Methodsmentioning

confidence: 99%

Toward Multiscale Measurement-Informed Methane Inventories: Reconciling Bottom-Up Site-Level Inventories with Top-Down Measurements Using Continuous Monitoring Systems

Daniels

Wang

Ravikumar

et al. 2023

Environ. Sci. Technol.

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Government policies and corporate strategies aimed at reducing methane emissions from the oil and gas sector increasingly rely on measurement-informed, site-level emission inventories, as conventional bottom-up inventories poorly capture temporal variability and the heavy-tailed nature of methane emissions. This work is based on an 11-month methane measurement campaign at oil and gas production sites. We find that operator-level top-down methane measurements are lower during the end-of-project phase than during the baseline phase. However, gaps persist between end-of-project topdown measurements and bottom-up site-level inventories, which we reconcile with high-frequency data from continuous monitoring systems (CMS). Specifically, we use CMS to (i) validate specific snapshot measurements and determine how they relate to the temporal emission profile of a given site and (ii) create a measurement-informed, site-level inventory that can be validated with top-down measurements to update conventional bottom-up inventories. This work presents a real-world demonstration of how to reconcile CMS rate estimates and top-down snapshot measurements jointly with bottom-up inventories at the site level. More broadly, it demonstrates the importance of multiscale measurements when creating measurement-informed, site-level emission inventories, which is a critical aspect of recent regulatory requirements in the Inflation Reduction Act, voluntary methane initiatives such as the Oil and Gas Methane Partnership 2.0, and corporate strategies.

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Evaluating methane emission quantification performance and uncertainty of aerial technologies via high-volume single-blind controlled releases

Cited by 13 publications

References 26 publications

Technological Maturity of Aircraft-Based Methane Sensing for Greenhouse Gas Mitigation

Technological Maturity of Aircraft-Based Methane Sensing for Greenhouse Gas Mitigation

Measuring Carbon Dioxide Emissions From Liquefied Natural Gas (LNG) Terminals With Imaging Spectroscopy

Toward Multiscale Measurement-Informed Methane Inventories: Reconciling Bottom-Up Site-Level Inventories with Top-Down Measurements Using Continuous Monitoring Systems

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