Your search keyword '"Rutherford, Jeffrey S."' showing total 5 results

1. Comparing Continuous Methane Monitoring Technologies for High-Volume Emissions: A Single-Blind Controlled Release Study

Author

Chen, Zhenlin, Abbadi, Sahar H El, Sherwin, Evan D, Burdeau, Philippine M, Rutherford, Jeffrey S, Chen, Yuanlei, Zhang, Zhan, and Brandt, Adam R

Subjects

Control Engineering, Mechatronics and Robotics, Engineering, Climate Action

Published

2024

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

Author

Abbadi, Sahar H El, Chen, Zhenlin, Burdeau, Philippine M, Rutherford, Jeffrey S, Chen, Yuanlei, Zhang, Zhan, Sherwin, Evan D, and Brandt, Adam R

Subjects

Environmental Sciences, Environmental Management, Climate Action, Methane, Aircraft, Greenhouse Gases, Environmental Monitoring, Climate Change, Air Pollutants, remote sensing, controlled release, methane, oil and gas, climate change, energy

Abstract

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 single-blind measurements across all five platforms to evaluate their ability to detect and quantify emissions that range from 1 to over 1,500 kg(CH4)/h. Aircraft consistently quantified releases above 10 kg(CH4)/h, and GHGSat-AV and Insight M detected emissions below 5 kg(CH4)/h. Fully blinded quantification estimates for platforms using downward-facing imaging spectrometers have parity slopes ranging from 0.76 to 1.13, with R2 values of 0.61 to 0.93; the platform using continuous air sampling has a parity slope of 0.5 (R2 = 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.

Published

2024

3. Single-blind test of nine methane-sensing satellite systems from three continents

Author

Sherwin, Evan D, El Abbadi, Sahar H, Burdeau, Philippine M, Zhang, Zhan, Chen, Zhenlin, Rutherford, Jeffrey S, Chen, Yuanlei, and Brandt, Adam R

Subjects

Earth Sciences, Atmospheric Sciences, Climate Action, Meteorology & Atmospheric Sciences, Atmospheric sciences

Abstract

Abstract. Satellite-based remote sensing enables detection and mitigation of large point sources of climate-warming methane. These satellites will have the greatest impact if stakeholders have a clear-eyed assessment of their capabilities. We performed a single-blind test of nine methane-sensing satellites from three continents and five countries, including both commercial and government satellites. Over 2 months, we conducted 82 controlled methane releases during satellite overpasses. Six teams analyzed the resulting data, producing 134 estimates of methane emissions. Of these, 80 (58 %) were correctly identified, with 46 true positive detections (34 %) and 34 true negative non-detections (25 %). There were 41 false negatives, in which teams missed a true emission, and 0 false positives, in which teams incorrectly claimed methane was present. All eight satellites that were given a nonzero emission detected methane at least once, including the first single-blind evaluation of the EnMAP, Gaofen 5, and Ziyuan 1 systems. In percent terms, quantification error across all satellites and teams is similar to aircraft-based methane remote sensing systems, with 55 % of mean estimates falling within ±50 % of the metered value. Although teams correctly detected emissions as low as 0.03 metric tons of methane per hour, it is unclear whether detection performance in this test is representative of real-world field performance. Full retrieval fields submitted by all teams suggest that in some cases it may be difficult to distinguish true emissions from background artifacts without a known source location. Cloud interference is significant and appears to vary across teams and satellites. This work confirms the basic efficacy of the tested satellite systems in detecting and quantifying methane, providing additional insight into detection limits and informing experimental design for future satellite-focused controlled methane release testing campaigns.

Published

2024

4. Single-blind validation of space-based point-source detection and quantification of onshore methane emissions

Author

Sherwin, Evan D, Rutherford, Jeffrey S, Chen, Yuanlei, Aminfard, Sam, Kort, Eric A, Jackson, Robert B, and Brandt, Adam R

Subjects

Geomatic Engineering, Engineering, Climate Action

Abstract

Satellites are increasingly seen as a tool for identifying large greenhouse gas point sources for mitigation, but independent verification of satellite performance is needed for acceptance and use by policy makers and stakeholders. We conduct to our knowledge the first single-blind controlled methane release testing of satellite-based methane emissions detection and quantification, with five independent teams analyzing data from one to five satellites each for this desert-based test. Teams correctly identified 71% of all emissions, ranging from 0.20 [0.19, 0.21] metric tons per hour (t/h) to 7.2 [6.8, 7.6] t/h. Three-quarters (75%) of quantified estimates fell within ± 50% of the metered value, comparable to airplane-based remote sensing technologies. The relatively wide-area Sentinel-2 and Landsat 8 satellites detected emissions as low as 1.4 [1.3, 1.5, 95% confidence interval] t/h, while GHGSat's targeted system quantified a 0.20 [0.19, 0.21] t/h emission to within 13%. While the fraction of global methane emissions detectable by satellite remains unknown, we estimate that satellite networks could see 19-89% of total oil and natural gas system emissions detected in a recent survey of a high-emitting region.

Published

2023

5. Closing the methane gap in US oil and natural gas production emissions inventories

Author

Rutherford, Jeffrey S, Sherwin, Evan D, Ravikumar, Arvind P, Heath, Garvin A, Englander, Jacob, Cooley, Daniel, Lyon, David, Omara, Mark, Langfitt, Quinn, and Brandt, Adam R

Subjects

Earth Sciences, Atmospheric Sciences, Environmental Sciences, Climate Action

Abstract

Methane (CH4) emissions from oil and natural gas (O&NG) systems are an important contributor to greenhouse gas emissions. In the United States, recent synthesis studies of field measurements of CH4 emissions at different spatial scales are ~1.5-2× greater compared to official greenhouse gas inventory (GHGI) estimates, with the production-segment as the dominant contributor to this divergence. Based on an updated synthesis of measurements from component-level field studies, we develop a new inventory-based model for CH4 emissions, for the production-segment only, that agrees within error with recent syntheses of site-level field studies and allows for isolation of equipment-level contributions. We find that unintentional emissions from liquid storage tanks and other equipment leaks are the largest contributors to divergence with the GHGI. If our proposed method were adopted in the United States and other jurisdictions, inventory estimates could better guide CH4 mitigation policy priorities.

Published

2021