Your search keyword '"Duren, Riley M"' showing total 5 results

1. Quantifying methane emissions from the global scale down to point sources using satellite observations of atmospheric methane.

Author

Jacob, Daniel J., Varon, Daniel J., Cusworth, Daniel H., Dennison, Philip E., Frankenberg, Christian, Gautam, Ritesh, Guanter, Luis, Kelley, John, McKeever, Jason, Ott, Lesley E., Poulter, Benjamin, Qu, Zhen, Thorpe, Andrew K., Worden, John R., and Duren, Riley M.

Subjects

ATMOSPHERIC methane, METHANE, MULTISPECTRAL imaging, IMAGE sensors, SPATIAL resolution, PARIS Agreement (2016)

Abstract

We review the capability of current and scheduled satellite observations of atmospheric methane in the shortwave infrared (SWIR) to quantify methane emissions from the global scale down to point sources. We cover retrieval methods, precision and accuracy requirements, inverse and mass balance methods for inferring emissions, source detection thresholds, and observing system completeness. We classify satellite instruments as area flux mappers and point source imagers, with complementary attributes. Area flux mappers are high-precision (<1 %) instruments with 0.1–10 km pixel size designed to quantify total methane emissions on regional to global scales. Point source imagers are fine-pixel (<60 m) instruments designed to quantify individual point sources by imaging of the plumes. Current area flux mappers include GOSAT (2009–present), which provides a high-quality record for interpretation of long-term methane trends, and TROPOMI (2018–present), which provides global continuous daily mapping to quantify emissions on regional scales. These instruments already provide a powerful resource to quantify national methane emissions in support of the Paris Agreement. Current point source imagers include the GHGSat constellation and several hyperspectral and multispectral land imaging sensors (PRISMA, Sentinel-2, Landsat-8/9, WorldView-3), with detection thresholds in the 100–10 000 kg h -1 range that enable monitoring of large point sources. Future area flux mappers, including MethaneSAT, GOSAT-GW, Sentinel-5, GeoCarb, and CO2M, will increase the capability to quantify emissions at high resolution, and the MERLIN lidar will improve observation of the Arctic. The averaging times required by area flux mappers to quantify regional emissions depend on pixel size, retrieval precision, observation density, fraction of successful retrievals, and return times in a way that varies with the spatial resolution desired. A similar interplay applies to point source imagers between detection threshold, spatial coverage, and return time, defining an observing system completeness. Expanding constellations of point source imagers including GHGSat and Carbon Mapper over the coming years will greatly improve observing system completeness for point sources through dense spatial coverage and frequent return times. [ABSTRACT FROM AUTHOR]

Published

2022

2. A multi-city urban atmospheric greenhouse gas measurement data synthesis.

Author

Mitchell, Logan E., Lin, John C., Hutyra, Lucy R., Bowling, David R., Cohen, Ronald C., Davis, Kenneth J., DiGangi, Elizabeth, Duren, Riley M., Ehleringer, James R., Fain, Clayton, Falk, Matthias, Guha, Abhinav, Karion, Anna, Keeling, Ralph F., Kim, Jooil, Miles, Natasha L., Miller, Charles E., Newman, Sally, Pataki, Diane E., and Prinzivalli, Steve

Subjects

GREENHOUSE gases, ATMOSPHERIC methane, CARBON monoxide, CARBON dioxide, EMISSIONS (Air pollution), GREENHOUSE gas mitigation

Abstract

Urban regions emit a large fraction of anthropogenic emissions of greenhouse gases (GHG) such as carbon dioxide (CO2) and methane (CH4) that contribute to modern-day climate change. As such, a growing number of urban policymakers and stakeholders are adopting emission reduction targets and implementing policies to reach those targets. Over the past two decades research teams have established urban GHG monitoring networks to determine how much, where, and why a particular city emits GHGs, and to track changes in emissions over time. Coordination among these efforts has been limited, restricting the scope of analyses and insights. Here we present a harmonized data set synthesizing urban GHG observations from cities with monitoring networks across North America that will facilitate cross-city analyses and address scientific questions that are difficult to address in isolation. Measurement(s) carbon dioxide • methane • carbon monoxide Technology Type(s) spectroscopy Sample Characteristic - Environment city Sample Characteristic - Location North America [ABSTRACT FROM AUTHOR]

Published

2022

3. Potential of next-generation imaging spectrometers to detect and quantify methane point sources from space.

Author

Cusworth, Daniel H., Jacob, Daniel J., Varon, Daniel J., Chan Miller, Christopher, Liu, Xiong, Chance, Kelly, Thorpe, Andrew K., Duren, Riley M., Miller, Charles E., Thompson, David R., Frankenberg, Christian, Guanter, Luis, and Randles, Cynthia A.

Subjects

SPECTROMETERS, ATMOSPHERIC methane, SURFACE of the earth, METHANE, SPACE-based radar, GAS fields, MICROWAVE radiometers

Abstract

We examine the potential for global detection of methane plumes from individual point sources with the new generation of spaceborne imaging spectrometers (EnMAP, PRISMA, EMIT, SBG, CHIME) scheduled for launch in 2019–2025. These instruments are designed to map the Earth's surface at high spatial resolution (30m×30m) and have a spectral resolution of 7–10 nm in the 2200–2400 nm band that should also allow useful detection of atmospheric methane. We simulate scenes viewed by EnMAP (10 nm spectral resolution, 180 signal-to-noise ratio) using the EnMAP end-to-end simulation tool with superimposed methane plumes generated by large-eddy simulations. We retrieve atmospheric methane and surface reflectivity for these scenes using the IMAP-DOAS optimal estimation algorithm. We find an EnMAP precision of 3 %–7 % for atmospheric methane depending on surface type. This allows effective single-pass detection of methane point sources as small as 100 kg h -1 depending on surface brightness, surface homogeneity, and wind speed. Successful retrievals over very heterogeneous surfaces such as an urban mosaic require finer spectral resolution. We tested the EnMAP capability with actual plume observations over oil/gas fields in California from the Airborne Visible/Infrared Imaging Spectrometer – Next Generation (AVIRIS-NG) sensor (3m×3m pixel resolution, 5 nm spectral resolution, SNR 200–400), by spectrally and spatially downsampling the AVIRIS-NG data to match EnMAP instrument specifications. Results confirm that EnMAP can successfully detect point sources of ∼100 kg h -1 over bright surfaces. Source rates inferred with a generic integrated mass enhancement (IME) algorithm were lower for EnMAP than for AVIRIS-NG. Better agreement may be achieved with a more customized IME algorithm. Our results suggest that imaging spectrometers in space could play an important role in the future for quantifying methane emissions from point sources worldwide. [ABSTRACT FROM AUTHOR]

Published

2019

4. Airborne DOAS retrievals of methane, carbon dioxide, and water vapor concentrations at high spatial resolution: application to AVIRIS-NG.

Author

Thorpe, Andrew K., Frankenberg, Christian, Thompson, David R., Duren, Riley M., Aubrey, Andrew D., Bue, Brian D., Green, Robert O., Gerilowski, Konstantin, Krings, Thomas, Borchardt, Jakob, Kort, Eric A., Sweeney, Colm, Conley, Stephen, Roberts, Dar A., and Dennison, Philip E.

Subjects

TRACE gases, AIRBORNE Visible/Infrared Imaging Spectrometer (AVIRIS), ATMOSPHERIC water vapor, CARBON dioxide mitigation, ATMOSPHERIC methane

Abstract

At local scales, emissions of methane and carbon dioxide are highly uncertain. Localized sources of both trace gases can create strong local gradients in its columnar abundance, which can be discerned using absorption spectroscopy at high spatial resolution. In a previous study, more than 250 methane plumes were observed in the San Juan Basin near Four Corners during April 2015 using the next-generation Airborne Visible/Infrared Imaging Spectrometer (AVIRIS-NG) and a linearized matched filter. For the first time, we apply the iterative maximum a posteriori differential optical absorption spectroscopy (IMAP-DOAS) method to AVIRIS-NG data and generate gas concentration maps for methane, carbon dioxide, and water vapor plumes. This demonstrates a comprehensive greenhouse gas monitoring capability that targets methane and carbon dioxide, the two dominant anthropogenic climate-forcing agents. Water vapor results indicate the ability of these retrievals to distinguish between methane and water vapor despite spectral interference in the shortwave infrared. We focus on selected cases from anthropogenic and natural sources, including emissions from mine ventilation shafts, a gas processing plant, tank, pipeline leak, and natural seep. In addition, carbon dioxide emissions were mapped from the flue-gas stacks of two coal-fired power plants and a water vapor plume was observed from the combined sources of cooling towers and cooling ponds. Observed plumes were consistent with known and suspected emission sources verified by the true color AVIRIS-NG scenes and higher-resolution Google Earth imagery. Real-time detection and geolocation of methane plumes by AVIRIS-NG provided unambiguous identification of individual emission source locations and communication to a ground team for rapid follow-up. This permitted verification of a number of methane emission sources using a thermal camera, including a tank and buried natural gas pipeline. [ABSTRACT FROM AUTHOR]

Published

2017

5. Improved methane emission estimates using AVIRIS-NG and an Airborne Doppler Wind Lidar.

Author

Thorpe, Andrew K., O'Handley, Christopher, Emmitt, George D., DeCola, Philip L., Hopkins, Francesca M., Yadav, Vineet, Guha, Abhinav, Newman, Sally, Herner, Jorn D., Falk, Matthias, and Duren, Riley M.

Subjects

*DOPPLER lidar, *METHANE, *INFRARED imaging, *METEOROLOGICAL stations, *WIND speed, *ATMOSPHERIC methane

Abstract

Estimating methane (CH 4) emission rates using quantitative CH 4 retrievals from the Next Generation Airborne Visible/Infrared Imaging Spectrometer (AVIRIS-NG) requires the use of wind speeds. Model wind speeds have limited temporal and spatial resolution, meteorological station wind data are of variable quality and are often not available near observed plumes, and the use of ultrasonic anemometers co-located with methane sources is impractical for AVIRIS-NG flight campaigns with daily coverage of thousands of square kilometers. Given these limitations, this study focused on the use of the Twin Otter Doppler Wind Lidar (TODWL) to measure near surface winds and provide coincident measurements to CH 4 plumes observed with AVIRIS-NG. In a controlled release experiment, TODWL observed wind speed and direction agreed well with ultrasonic anemometer measurements and CH 4 emission rates derived from TODWL observations were more accurate than those using the ultrasonic anemometer or model winds during periods of stable winds. During periods exhibiting rapid shifts in wind speed and direction, estimating emission rates proved more challenging irrespective of the use of model, ultrasonic anemometer, or TODWL wind data. Overall, TODWL was able to provide reasonably accurate wind measurements and emission rate estimates despite the variable wind conditions and excessive flight level turbulence which impacted near surface measurement density. TODWL observed winds were also used to constrain CH 4 emissions at a refinery, landfill, wastewater facility, and dairy digester. At these sites, TODWL wind measurements agreed well with wind observations from nearby meteorological stations, and when combined with quantitative CH 4 plume imagery, yielded emission rate estimates that were similar to those obtained using model winds. This study demonstrates the utility of combining TODWL and AVIRIS-NG CH 4 measurements and emphasizes the potential benefits of integrating both instruments on a single aircraft for future deployments. • Airborne Doppler Wind Lidar (ADWL) and AVIRIS-NG used to estimate methane emissions • Emissions characterized for controlled release and multiple emission sectors • ADWL winds agreed closely with ultrasonic anemometer and meteorological stations • ADWL derived emissions sometimes more accurate than using anemometer/modelled winds • Integrating both instruments on single aircraft would reduce emission uncertainty [ABSTRACT FROM AUTHOR]

Published

2021