Search

Your search keyword '"Davis, Kenneth J."' showing total 642 results
Start Over Author "Davis, Kenneth J."
642 results on '"Davis, Kenneth J."'

1. Confronting the water potential information gap

Author

Novick, Kimberly A, Ficklin, Darren L, Baldocchi, Dennis, Davis, Kenneth J, Ghezzehei, Teamrat A, Konings, Alexandra G, MacBean, Natasha, Raoult, Nina, Scott, Russell L, Shi, Yuning, Sulman, Benjamin N, and Wood, Jeffrey D

Subjects
Earth Sciences, Physical Geography and Environmental Geoscience, Meteorology & Atmospheric Sciences, Physical geography and environmental geoscience
Abstract

Water potential directly controls the function of leaves, roots, and microbes, and gradients in water potential drive water flows throughout the soil-plant-atmosphere continuum. Notwithstanding its clear relevance for many ecosystem processes, soil water potential is rarely measured in-situ, and plant water potential observations are generally discrete, sparse, and not yet aggregated into accessible databases. These gaps limit our conceptual understanding of biophysical responses to moisture stress and inject large uncertainty into hydrologic and land surface models. Here, we outline the conceptual and predictive gains that could be made with more continuous and discoverable observations of water potential in soils and plants. We discuss improvements to sensor technologies that facilitate in situ characterization of water potential, as well as strategies for building new networks that aggregate water potential data across sites. We end by highlighting novel opportunities for linking more representative site-level observations of water potential to remotely-sensed proxies. Together, these considerations offer a roadmap for clearer links between ecohydrological processes and the water potential gradients that have the 'potential' to substantially reduce conceptual and modeling uncertainties.

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, Prinzivalli, Steve, Ren, Xinrong, Rice, Andrew, Richardson, Scott J, Sargent, Maryann, Stephens, Britton B, Turnbull, Jocelyn C, Verhulst, Kristal R, Vogel, Felix, Weiss, Ray F, Whetstone, James, and Wofsy, Steven C

Subjects
Climate Action, Sustainable Cities and Communities
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.

Published
2022

4. Integrating continuous atmospheric boundary layer and tower-based flux measurements to advance understanding of land-atmosphere interactions

Author

Helbig, Manuel, Gerken, Tobias, Beamesderfer, Eric R, Baldocchi, Dennis D, Banerjee, Tirtha, Biraud, Sébastien C, Brown, William OJ, Brunsell, Nathaniel A, Burakowski, Elizabeth A, Burns, Sean P, Butterworth, Brian J, Chan, W Stephen, Davis, Kenneth J, Desai, Ankur R, Fuentes, Jose D, Hollinger, David Y, Kljun, Natascha, Mauder, Matthias, Novick, Kimberly A, Perkins, John M, Rahn, David A, Rey-Sanchez, Camilo, Santanello, Joseph A, Scott, Russell L, Seyednasrollah, Bijan, Stoy, Paul C, Sullivan, Ryan C, de Arellano, Jordi Vilà-Guerau, Wharton, Sonia, Yi, Chuixiang, and Richardson, Andrew D

Subjects
Earth Sciences, Atmospheric Sciences, Eddy covariance, Boundary layer, Land-atmosphere, Remote sensing, Atmospheric inversion models, Biological Sciences, Agricultural and Veterinary Sciences, Meteorology & Atmospheric Sciences, Agricultural, veterinary and food sciences, Biological sciences, Earth sciences
Abstract

The atmospheric boundary layer mediates the exchange of energy, matter, and momentum between the land surface and the free troposphere, integrating a range of physical, chemical, and biological processes and is defined as the lowest layer of the atmosphere (ranging from a few meters to 3 km). In this review, we investigate how continuous, automated observations of the atmospheric boundary layer can enhance the scientific value of co-located eddy covariance measurements of land-atmosphere fluxes of carbon, water, and energy, as are being made at FLUXNET sites worldwide. We highlight four key opportunities to integrate tower-based flux measurements with continuous, long-term atmospheric boundary layer measurements: (1) to interpret surface flux and atmospheric boundary layer exchange dynamics and feedbacks at flux tower sites, (2) to support flux footprint modelling, the interpretation of surface fluxes in heterogeneous and mountainous terrain, and quality control of eddy covariance flux measurements, (3) to support regional-scale modeling and upscaling of surface fluxes to continental scales, and (4) to quantify land-atmosphere coupling and validate its representation in Earth system models. Adding a suite of atmospheric boundary layer measurements to eddy covariance flux tower sites, and supporting the sharing of these data to tower networks, would allow the Earth science community to address new emerging research questions, better interpret ongoing flux tower measurements, and would present novel opportunities for collaborations between FLUXNET scientists and atmospheric and remote sensing scientists.

Published
2021

5. Author Correction: The FLUXNET2015 dataset and the ONEFlux processing pipeline for eddy covariance data.

Author

Pastorello, Gilberto, Trotta, Carlo, Canfora, Eleonora, Chu, Housen, Christianson, Danielle, Cheah, You-Wei, Poindexter, Cristina, Chen, Jiquan, Elbashandy, Abdelrahman, Humphrey, Marty, Isaac, Peter, Polidori, Diego, Reichstein, Markus, Ribeca, Alessio, van Ingen, Catharine, Vuichard, Nicolas, Zhang, Leiming, Amiro, Brian, Ammann, Christof, Arain, M Altaf, Ardö, Jonas, Arkebauer, Timothy, Arndt, Stefan K, Arriga, Nicola, Aubinet, Marc, Aurela, Mika, Baldocchi, Dennis, Barr, Alan, Beamesderfer, Eric, Marchesini, Luca Belelli, Bergeron, Onil, Beringer, Jason, Bernhofer, Christian, Berveiller, Daniel, Billesbach, Dave, Black, Thomas Andrew, Blanken, Peter D, Bohrer, Gil, Boike, Julia, Bolstad, Paul V, Bonal, Damien, Bonnefond, Jean-Marc, Bowling, David R, Bracho, Rosvel, Brodeur, Jason, Brümmer, Christian, Buchmann, Nina, Burban, Benoit, Burns, Sean P, Buysse, Pauline, Cale, Peter, Cavagna, Mauro, Cellier, Pierre, Chen, Shiping, Chini, Isaac, Christensen, Torben R, Cleverly, James, Collalti, Alessio, Consalvo, Claudia, Cook, Bruce D, Cook, David, Coursolle, Carole, Cremonese, Edoardo, Curtis, Peter S, D'Andrea, Ettore, da Rocha, Humberto, Dai, Xiaoqin, Davis, Kenneth J, De Cinti, Bruno, de Grandcourt, Agnes, De Ligne, Anne, De Oliveira, Raimundo C, Delpierre, Nicolas, Desai, Ankur R, Di Bella, Carlos Marcelo, di Tommasi, Paul, Dolman, Han, Domingo, Francisco, Dong, Gang, Dore, Sabina, Duce, Pierpaolo, Dufrêne, Eric, Dunn, Allison, Dušek, Jiří, Eamus, Derek, Eichelmann, Uwe, ElKhidir, Hatim Abdalla M, Eugster, Werner, Ewenz, Cacilia M, Ewers, Brent, Famulari, Daniela, Fares, Silvano, Feigenwinter, Iris, Feitz, Andrew, Fensholt, Rasmus, Filippa, Gianluca, Fischer, Marc, Frank, John, Galvagno, Marta, and Gharun, Mana

Abstract

The following authors were omitted from the original version of this Data Descriptor: Markus Reichstein and Nicolas Vuichard. Both contributed to the code development and N. Vuichard contributed to the processing of the ERA-Interim data downscaling. Furthermore, the contribution of the co-author Frank Tiedemann was re-evaluated relative to the colleague Corinna Rebmann, both working at the same sites, and based on this re-evaluation a substitution in the co-author list is implemented (with Rebmann replacing Tiedemann). Finally, two affiliations were listed incorrectly and are corrected here (entries 190 and 193). The author list and affiliations have been amended to address these omissions in both the HTML and PDF versions.

Published
2021

6. The FLUXNET2015 dataset and the ONEFlux processing pipeline for eddy covariance data.

Author

Pastorello, Gilberto, Trotta, Carlo, Canfora, Eleonora, Chu, Housen, Christianson, Danielle, Cheah, You-Wei, Poindexter, Cristina, Chen, Jiquan, Elbashandy, Abdelrahman, Humphrey, Marty, Isaac, Peter, Polidori, Diego, Reichstein, Markus, Ribeca, Alessio, van Ingen, Catharine, Vuichard, Nicolas, Zhang, Leiming, Amiro, Brian, Ammann, Christof, Arain, M Altaf, Ardö, Jonas, Arkebauer, Timothy, Arndt, Stefan K, Arriga, Nicola, Aubinet, Marc, Aurela, Mika, Baldocchi, Dennis, Barr, Alan, Beamesderfer, Eric, Marchesini, Luca Belelli, Bergeron, Onil, Beringer, Jason, Bernhofer, Christian, Berveiller, Daniel, Billesbach, Dave, Black, Thomas Andrew, Blanken, Peter D, Bohrer, Gil, Boike, Julia, Bolstad, Paul V, Bonal, Damien, Bonnefond, Jean-Marc, Bowling, David R, Bracho, Rosvel, Brodeur, Jason, Brümmer, Christian, Buchmann, Nina, Burban, Benoit, Burns, Sean P, Buysse, Pauline, Cale, Peter, Cavagna, Mauro, Cellier, Pierre, Chen, Shiping, Chini, Isaac, Christensen, Torben R, Cleverly, James, Collalti, Alessio, Consalvo, Claudia, Cook, Bruce D, Cook, David, Coursolle, Carole, Cremonese, Edoardo, Curtis, Peter S, D'Andrea, Ettore, da Rocha, Humberto, Dai, Xiaoqin, Davis, Kenneth J, Cinti, Bruno De, Grandcourt, Agnes de, Ligne, Anne De, De Oliveira, Raimundo C, Delpierre, Nicolas, Desai, Ankur R, Di Bella, Carlos Marcelo, Tommasi, Paul di, Dolman, Han, Domingo, Francisco, Dong, Gang, Dore, Sabina, Duce, Pierpaolo, Dufrêne, Eric, Dunn, Allison, Dušek, Jiří, Eamus, Derek, Eichelmann, Uwe, ElKhidir, Hatim Abdalla M, Eugster, Werner, Ewenz, Cacilia M, Ewers, Brent, Famulari, Daniela, Fares, Silvano, Feigenwinter, Iris, Feitz, Andrew, Fensholt, Rasmus, Filippa, Gianluca, Fischer, Marc, Frank, John, Galvagno, Marta, and Gharun, Mana

Abstract

The FLUXNET2015 dataset provides ecosystem-scale data on CO2, water, and energy exchange between the biosphere and the atmosphere, and other meteorological and biological measurements, from 212 sites around the globe (over 1500 site-years, up to and including year 2014). These sites, independently managed and operated, voluntarily contributed their data to create global datasets. Data were quality controlled and processed using uniform methods, to improve consistency and intercomparability across sites. The dataset is already being used in a number of applications, including ecophysiology studies, remote sensing studies, and development of ecosystem and Earth system models. FLUXNET2015 includes derived-data products, such as gap-filled time series, ecosystem respiration and photosynthetic uptake estimates, estimation of uncertainties, and metadata about the measurements, presented for the first time in this paper. In addition, 206 of these sites are for the first time distributed under a Creative Commons (CC-BY 4.0) license. This paper details this enhanced dataset and the processing methods, now made available as open-source codes, making the dataset more accessible, transparent, and reproducible.

Published
2020

8. The Atmospheric Carbon and Transport (ACT)-America Mission

Author

Davis, Kenneth J., Browell, Edward V., Feng, Sha, Lauvaux, Thomas, Obland, Michael D., Pal, Sandip, Baier, Bianca C., Baker, David F., Baker, Ian T., Barkley, Zachary R., Bowman, Kevin W., Cui, Yu Yan, Denning, A. Scott, DiGangi, Joshua P., Dobler, Jeremy T., Fried, Alan, Gerken, Tobias, Keller, Klaus, Lin, Bing, Nehrir, Amin R., Normile, Caroline P., O’Dell, Christopher W., Ott, Lesley E., Roiger, Anke, Schuh, Andrew E., Sweeney, Colm, Wei, Yaxing, Weir, Brad, Xue, Ming, and Williams, Christopher A.

Published
2021

9. Automated Integration of Continental-Scale Observations in Near-Real Time for Simulation and Analysis of Biosphere–Atmosphere Interactions

Author

Durden, David J., Metzger, Stefan, Chu, Housen, Collier, Nathan, Davis, Kenneth J., Desai, Ankur R., Kumar, Jitendra, Wieder, William R., Xu, Min, Hoffman, Forrest M., Filipe, Joaquim, Editorial Board Member, Ghosh, Ashish, Editorial Board Member, Prates, Raquel Oliveira, Editorial Board Member, Zhou, Lizhu, Editorial Board Member, Nichols, Jeffrey, editor, Verastegui, Becky, editor, Maccabe, Arthur ‘Barney’, editor, Hernandez, Oscar, editor, Parete-Koon, Suzanne, editor, and Ahearn, Theresa, editor

Published
2020
Full Text
View/download PDF

10. Estimation of Urban Greenhouse Gas Fluxes from Mole Fraction Measurements Using Monin–Obukhov Similarity Theory.

Author

Kenion, Helen C., Davis, Kenneth J., Miles, Natasha L., Monteiro, Vanessa C., Richardson, Scott J., and Horne, Jason P.

Subjects
*MOLE fraction, *LAND-atmosphere interactions, *GREENHOUSE gases, *HEIGHT measurement, *METEOROLOGICAL stations
Abstract

The purpose of this study is to determine whether urban greenhouse gas (GHG) fluxes can be quantified from tower-based mole fraction measurements using Monin–Obukhov similarity theory (MOST). Tower-based GHG mole fraction networks are used in many cities to quantify whole-city GHG emissions. Local-scale, micrometeorological flux estimates would complement whole-city estimates from atmospheric inversions. CO2 mole fraction and eddy-covariance flux data at an urban site in Indianapolis, Indiana, from October 2020 through January 2022 are analyzed. Using MOST flux–variance and flux–gradient relationships, CO2 fluxes were calculated using these mole fraction data and compared to the eddy-covariance fluxes. MOST-based fluxes were calculated using varying measurement heights and methods of estimating stability. The MOST flux–variance relationship method showed good temporal correlation with eddy-covariance fluxes at this site but overestimated flux magnitudes. Fluxes calculated using flux–gradient relationships showed lower temporal correlation with eddy-covariance fluxes but closer magnitudes to eddy-covariance fluxes. Measurement heights closer to ground level produce more precise flux estimates for both MOST-based methods. For flux–gradient methods, flux estimates are more accurate and precise when low-altitude measurements are combined with a large vertical separation between measurement heights. When stability estimates based on eddy-covariance flux measurements are replaced with stability estimates based on the weather station or net radiation data, the MOST-based fluxes still capture the temporal patterns measured via eddy covariance. Based on these results, MOST can be used to estimate the temporal patterns in local GHG fluxes at mole fraction tower sites, complementing the small number of eddy-covariance flux measurements available in urban settings. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

13. Assessment of methane emissions from the U.S. oil and gas supply chain

Author

Alvarez, Ramón A., Zavala-Araiza, Daniel, Lyon, David R., Allen, David T., Barkley, Zachary R., Brandt, Adam R., Davis, Kenneth J., Herndon, Scott C., Jacob, Daniel J., Karion, Anna, Kort, Eric A., Lamb, Brian K., Lauvaux, Thomas, Maasakkers, Joannes D., Marchese, Anthony J., Omara, Mark, Pacala, Stephen W., Peischl, Jeff, Robinson, Allen L., Shepson, Paul B., Sweeney, Colm, Townsend-Small, Amy, Wofsy, Steven C., and Hamburg, Steven P.

Published
2018

15. The MODIS (Collection V005) BRDF/albedo product: Assessment of spatial representativeness over forested landscapes

Author

Román, Miguel O., Schaaf, Crystal B., Woodcock, Curtis E., Strahler, Alan H., Yang, Xiaoyuan, Braswell, Rob H., Curtis, Peter S., Davis, Kenneth J., Dragoni, Danilo, and Goulden, Michael L.

Subjects
MODIS, BRDF, surface albedo, validation, spatial analysis, remote sensing, AmeriFlux, FLUXNET, EOS Land Validation Core Sites, ETM+, 6S, geostatistics
Abstract

A new methodology for establishing the spatial representativeness of tower albedo measurements that are routinely used in validation of satellite retrievals from global land surface albedo and reflectance anisotropy products is presented. This method brings together knowledge of the intrinsic biophysical properties of a measurement site, and the surrounding landscape to produce a number of geostatistical attributes that describe the overall variability, spatial extent, strength of the spatial correlation, and spatial structure of surface albedo patterns at separate seasonal periods throughout the year. Variogram functions extracted from Enhanced Thematic Mapper Plus (ETM+) retrievals of surface albedo using multiple spatial and temporal thresholds were used to assess the degree to which a given point (tower) measurement is able to capture the intrinsic variability of the immediate landscape extending to a satellite pixel. A validation scheme was implemented over a wide range of forested landscapes, looking at both deciduous and coniferous sites, from tropical to boreal ecosystems. The experiment focused on comparisons between tower measurements of surface albedo acquired at local solar noon and matching retrievals from the MODerate Resolution Imaging Spectroradiometer (MODIS) (Collection V005) Bidirectional Reflectance Distribution Function (BRDF)/albedo algorithm. Assessments over a select group of field stations with comparable landscape features and daily retrieval scenarios further demonstrate the ability of this technique to identify measurement sites that contain the intrinsic spatial and seasonal features of surface albedo over sufficiently large enough footprints for use in modeling and remote sensing studies. This approach, therefore, improves our understanding of product uncertainty both in terms of the representativeness of the field data and its relationship to the larger satellite pixel.

Published
2009

16. Regional inversion shows promise in capturing extreme-event-driven CO2 flux anomalies but is limited by atmospheric CO2 observational coverage

Author

Byrne, Brendan, primary, Liu, Junjie, additional, Bowman, Kevin W., additional, Yin, Yi, additional, Yun, Jeongmin, additional, Ferreira, Gabriel, additional, Ogle, Stephen, additional, Baskaran, Latha, additional, He, Liyin, additional, Li, Xing, additional, Xiao, Jingfeng, additional, and Davis, Kenneth J., additional

Published
2023
Full Text
View/download PDF

18. Temporal Error Correlations in a Terrestrial Carbon Cycle Model Derived by Comparison to Carbon Dioxide Eddy Covariance Flux Tower Measurements.

Author

Wesloh, Daniel, Keller, Klaus, Feng, Sha, Lauvaux, Thomas, and Davis, Kenneth J.

Subjects
ATMOSPHERIC carbon dioxide, CARBON cycle, EDDY flux, CARBON dioxide, STATISTICAL correlation, RESEARCH personnel, AUTOCORRELATION (Statistics)
Abstract

Atmospheric CO2 flux inversions require as input an estimate of spatial and temporal correlations of errors in their estimate of the prior mean. Some previous studies have used the differences in CO2 daily average flux estimates produced by terrestrial carbon cycle models and eddy covariance measurements to constrain the flux error correlations. Since inversions are starting to resolve the daily cycle, we set out to examine the correlations at sub‐daily time scales, as well as the correlations across years. To this end, we examine the autocorrelations in the difference between net ecosystem‐atmosphere exchange measurements from 75 AmeriFlux towers and temporally downscaled high‐spatial‐resolution flux estimates from the Carnegie‐Ames‐Stanford Approach (CASA) terrestrial carbon cycle model. We find that the daily cycle is prominent in these hourly autocorrelations and that these autocorrelations persist across years. We propose a family of functions to model these temporal correlations in atmospheric inversions, and use cross validation to determine which of the correlation functions best fits autocorrelation data from towers not in the training set. Correlation functions with a component that attempts to model the daily cycle in the differences match correlations from other towers better than those without. Those models that reproduce the same correlation structures at 1‐year intervals while modulating the amplitudes of the correlations between those intervals improve the fit still further. Plain Language Summary: Atmospheric CO2 flux inversions rely heavily on assumptions about errors in the initial flux estimate. If these errors are related in time or in space, inversions need to represent both the shape and the size of the likely errors. Previous studies have looked at the shape of the errors in daily average fluxes, but fewer have looked at the relationship between errors in one part of a day and in another part of that day, or between 1 year and the next. The study examines relationships in differences between measured and computer‐predicted ecosystem‐atmosphere carbon dioxide fluxes. There are strong relationships between flux errors separated by multiple years. Current attempts to solve for true ecosystem‐atmosphere fluxes using atmospheric data do not take these multi‐year relationships into consideration. Accounting for the multi‐year relationships may improve our ability to determine the true ecosystem‐atmosphere CO2 fluxes. We look for descriptions of these relationships that researchers can use when using atmospheric data to improve the computer‐predicted CO2 fluxes. Key Points: CO2 flux model‐data differences have autocorrelations that recur at intervals of a year with little decay over multiple yearsThese autocorrelations are largely caused by errors in the representation of the daily cycleWe can treat these persistent errors in the daily cycle either as prior flux error correlations or by corrections to the prior flux model [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

19. Flood Impacts on Net Ecosystem Exchange in the Midwestern and Southern United States in 2019

Author

Balashov, Nikolay V., Balashov, Nikolay V., Ott, Lesley E., Weir, Brad, Basu, Sourish, Davis, Kenneth J., Miles, Natasha L., Thompson, Anne M., Stauffer, Ryan M., Balashov, Nikolay V., Balashov, Nikolay V., Ott, Lesley E., Weir, Brad, Basu, Sourish, Davis, Kenneth J., Miles, Natasha L., Thompson, Anne M., and Stauffer, Ryan M.

Abstract

Climate extremes such as droughts, floods, heatwaves, frosts, and windstorms add considerable variability to the global year-to-year increase in atmospheric CO2 through their influence on terrestrial ecosystems. While the impact of droughts on terrestrial ecosystems has received considerable attention, the response to flooding is not well understood. To improve upon this knowledge, the impact of the 2019 anomalously wet conditions over the Midwest and Southern US on CO2 vegetation fluxes is examined in the context of 2017–2018 when such precipitation anomalies were not observed. CO2 is simulated with NASA's Global Earth Observing System (GEOS) combined with the Low-order Flux Inversion, where fluxes of CO2 are estimated using a suite of remote sensing measurements including greenness, night lights, and fire radiative power as well as with a bias correction based on insitu observations. Net ecosystem exchange CO2 tracers are separated into the three regions covering the Midwest, South, and Eastern Texas and adjusted to match CO2 observations from towers located in Iowa, Mississippi, and Texas. Results indicate that for the Midwestern region consisting primarily of corn and soybeans crops, flooding contributes to a 15%–25% reduction of annual net carbon uptake in 2019 in comparison to 2017 and 2018. These results are supported by independent reports of changes in agricultural activity. For the Southern region, comprised mainly of non-crop vegetation, annual net carbon uptake is enhanced in 2019 by about 10%–20% in comparison to 2017 and 2018. These outcomes show the heterogeneity in effects that excess wetness can bring to diverse ecosystems.

Published
2023

22. Validation of Regional CO2 Concentrations in the ECMWF Real-Time Analysis and Carbon-Tracker Reanalysis with Airborne Observations from ACT-A Field Campaign

Author

Chen, Hans W, Zhang, Lily N, Zhang, Fuqing, Davis, Kenneth J, Luavaux, Thomas, Pal, Sandip, and Digangi, Joshua P

Subjects
Meteorology And Climatology
Abstract

Through verifying against hundreds of hours of airborne in-situ measurements from the NASA-sponsored Atmospheric Carbon and Transport – America (ACT-A) field campaign, this study systematically examines the regional uncertainties and biases of the carbon dioxide (CO2) concentrations from two of the state-of-the-art global analysis products, namely the real-time analysis from the European Center (EC) for Medium Range Forecasting and NOAA’s near real-time Carbon Tracker (CT) reanalysis. It is found that both the EC and CT-NRT analyses agree reasonably well with the independent ACT-A flight-level CO2 measurements in the free troposphere but the uncertainties are considerably larger in the boundary layer during both the summer months of 2016 and the winter months of 2017. There are also strong variabilities in accuracy and bias between seasons, and across three different subregions in the United States (Mid-Atlantic, Midwest and South). Overall, the analysis uncertainties of the EC and CT-NRT analyses in terms of root-mean square deviations against airborne data are comparable to each other, both of which are between 1-2 ppm in the free troposphere but can be as large as 10 ppm near the surface, which are grossly consistent with the difference between the two analyses. The current study not only provides systematic uncertainty estimates for both analysis products over North America but also demonstrated that these two independent estimates can be used to approximate the overall regional CO2 analysis uncertainties. Both statistics are important in future studies in quantifying the uncertainties of regional carbon concentration and flux estimates, as well as in assessing the impact of regional transport through more refined regional modeling and analysis systems.

Published
2019

23. Reconciling divergent estimates of oil and gas methane emissions

Author

Zavala-Araiza, Daniel, Lyon, David R., Alvarez, Ramón A., Davis, Kenneth J., Harriss, Robert, Herndon, Scott C., Karion, Anna, Kort, Eric Adam, Lamb, Brian K., Lan, Xin, Marchese, Anthony J., Pacala, Stephen W., Robinson, Allen L., Shepson, Paul B., Sweeney, Colm, Talbot, Robert, Townsend-Small, Amy, Yacovitch, Tara I., Zimmerle, Daniel J., and Hamburg, Steven P.

Published
2015

24. Arable Lands

Author

Tóth, Eszter, Barcza, Zoltán, Birkás, Márta, Gelybó, Györgyi, Zsembeli, József, Bottlik, László, Davis, Kenneth J., Haszpra, László, Kern, Anikó, Kljun, Natascha, Koós, Sándor, Kovács, Györgyi, Stingli, Attila, Farkas, Csilla, and Haszpra, László, editor

Published
2011
Full Text
View/download PDF

25. Methodologies

Author

Farkas, Csilla, Alberti, Giorgio, Balogh, János, Barcza, Zoltán, Birkás, Márta, Czóbel, Szilárd, Davis, Kenneth J, Führer, Ernő, Gelybó, Györgyi, Grosz, Balázs, Kljun, Natascha, Koós, Sándor, Machon, Attila, Marjanović, Hrvoje, Nagy, Zoltán, Peressotti, Alessandro, Pintér, Krisztina, Tóth, Eszter, Horváth, László, and Haszpra, László, editor

Published
2011
Full Text
View/download PDF

26. Continuous weekly monitoring of methane emissions from the Permian Basin by inversion of TROPOMI satellite observations

Author

Varon, Daniel J., primary, Jacob, Daniel J., additional, Hmiel, Benjamin, additional, Gautam, Ritesh, additional, Lyon, David R., additional, Omara, Mark, additional, Sulprizio, Melissa, additional, Shen, Lu, additional, Pendergrass, Drew, additional, Nesser, Hannah, additional, Qu, Zhen, additional, Barkley, Zachary R., additional, Miles, Natasha L., additional, Richardson, Scott J., additional, Davis, Kenneth J., additional, Pandey, Sudhanshu, additional, Lu, Xiao, additional, Lorente, Alba, additional, Borsdorff, Tobias, additional, Maasakkers, Joannes D., additional, and Aben, Ilse, additional

Published
2022
Full Text
View/download PDF

27. Data-driven diagnostics of terrestrial carbon dynamics over North America

Author

Xiao, Jingfeng, Ollinger, Scott V., Frolking, Steve, Hurtt, George C., Hollinger, David Y., Davis, Kenneth J., Pan, Yude, Zhang, Xiaoyang, Deng, Feng, Chen, Jiquan, Baldocchi, Dennis D., Law, Bevery E., Arain, M. Altaf, Desai, Ankur R., Richardson, Andrew D., Sun, Ge, Amiro, Brian, Margolis, Hank, Gu, Lianhong, Scott, Russell L., Blanken, Peter D., and Suyker, Andrew E.

Published
2014
Full Text
View/download PDF

32. Continuous weekly monitoring of methane emissions from the Permian Basin by inversion of TROPOMI satellite observations.

Author

Varon, Daniel J., Jacob, Daniel J., Hmiel, Benjamin, Gautam, Ritesh, Lyon, David R., Omara, Mark, Sulprizio, Melissa, Shen, Lu, Pendergrass, Drew, Nesser, Hannah, Qu, Zhen, Barkley, Zachary R., Miles, Natasha L., Richardson, Scott J., Davis, Kenneth J., Pandey, Sudhanshu, Lu, Xiao, Lorente, Alba, Borsdorff, Tobias, and Maasakkers, Joannes D.

Subjects
GAS wells, METHANE, CLIMATE change mitigation, NATURAL gas prices
Abstract

We quantify weekly methane emissions at 0.25 ∘ × 0.3125 ∘ (≈25 × 25 km 2) resolution from the Permian Basin, the largest oil production basin in the US, by inverse analysis of satellite observations from the TROPOspheric Monitoring Instrument (TROPOMI) from May 2018 to October 2020. The mean oil and gas emission from the region (± standard deviation of weekly estimates) was 3.7 ± 0.9 Tg a -1 , higher than previous TROPOMI inversion estimates that may have used biased prior emissions or background assumptions. We find strong week-to-week variability in emissions superimposed on longer-term trends, and these are consistent with independent inferences of temporal emission variability from tower, aircraft, and multispectral satellite data. New well development and natural gas spot price were significant drivers of variability in emissions over our study period but the concurrent 50 % increase in oil and gas production was not. The methane intensity (methane emitted per unit of methane gas produced) averaged 4.6 % ± 1.3 % and steadily decreased from 5 %–6 % in 2018 to 3 %–4 % in 2020. While the decreasing trend suggests improvement in operator practices during the study period, methane emissions from the Permian Basin remained high, with methane intensity an order of magnitude above the industry target of <0.2 %. Our success in using TROPOMI satellite observations for weekly estimates of emissions from a major oil production basin shows promise for application to near-real-time monitoring in support of climate change mitigation efforts. [ABSTRACT FROM AUTHOR]

Published
2023
Full Text
View/download PDF

34. Evaluating Global Atmospheric Inversions of Terrestrial Net Ecosystem Exchange CO 2 Over North America on Seasonal and Sub‐Continental Scales

Author

Cui, Yu Yan, primary, Zhang, Li, additional, Jacobson, Andrew R., additional, Johnson, Matthew S., additional, Philip, Sajeev, additional, Baker, David, additional, Chevallier, Frederic, additional, Schuh, Andrew E., additional, Liu, Junjie, additional, Crowell, Sean, additional, Peiro, Hélène E., additional, Deng, Feng, additional, Basu, Sourish, additional, and Davis, Kenneth J., additional

Published
2022
Full Text
View/download PDF

35. Airborne Lidar Measurements of XCO 2 in Synoptically Active Environment and Associated Comparisons With Numerical Simulations

Author

Walley, Samantha, primary, Pal, Sandip, additional, Campbell, Joel F., additional, Dobler, Jeremy, additional, Bell, Emily, additional, Weir, Brad, additional, Feng, Sha, additional, Lauvaux, Thomas, additional, Baker, David, additional, Blume, Nathan, additional, Erxleben, Wayne, additional, Fan, Tai‐Fang, additional, Lin, Bing, additional, McGregor, Doug, additional, Obland, Michael D., additional, O'Dell, Chris, additional, and Davis, Kenneth J., additional

Published
2022
Full Text
View/download PDF

37. Source decomposition of eddy-covariance CO2 flux measurements for evaluating a high-resolution urban CO2 emissions inventory

Author

Wu, Kai, primary, Davis, Kenneth J, additional, Miles, Natasha L, additional, Richardson, Scott J, additional, Lauvaux, Thomas, additional, Sarmiento, Daniel P, additional, Balashov, Nikolay V, additional, Keller, Klaus, additional, Turnbull, Jocelyn, additional, Gurney, Kevin R, additional, Liang, Jianming, additional, and Roest, Geoffrey, additional

Published
2022
Full Text
View/download PDF

42. 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., Prinzivalli, Steve, Ren, Xinrong, Rice, Andrew, Richardson, Scott J., Sargent, Maryann, Stephens, Britton B., Turnbull, Jocelyn C., Verhulst, Kristal R., Vogel, Felix, Weiss, Ray F., Whetstone, James, and Wofsy, Steven C.

Subjects
Statistics and Probability, Climate Action, Sustainable Cities and Communities, Library and Information Sciences, Statistics, Probability and Uncertainty, Computer Science Applications, Education, Information Systems
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.

Published
2022

46. Multi‐Season Evaluation of CO₂ Weather in OCO-2 MIP Models

Author

Zhang, Li, Davis, Kenneth J., Schuh, Andrew E., Jacobson, Andrew R., Pal, Sandip, Cui, Yu Yan, Baker, David, Crowell, Sean, Chevallier, Frederic, Remaud, Marine, Liu, Junjie, Weir, Brad, Philip, Sajeev, Johnson, Matthew S., Deng, Feng, and Basu, Sourish

Abstract

The ability of current global models to simulate the transport of CO₂ by mid-latitude, synoptic-scale weather systems (i.e., CO₂ weather) is important for inverse estimates of regional and global carbon budgets but remains unclear without comparisons to targeted measurements. Here, we evaluate ten models that participated in the Orbiting Carbon Observatory-2 model intercomparison project (OCO-2 MIP version 9) with intensive aircraft measurements collected from the Atmospheric Carbon Transport (ACT)-America mission. We quantify model-data differences in the spatial variability of CO₂ mole fractions, mean winds, and boundary layer depths in 27 mid-latitude cyclones spanning four seasons over the central and eastern United States. We find that the OCO-2 MIP models are able to simulate observed CO₂ frontal differences with varying degrees of success in summer and spring, and most underestimate frontal differences in winter and autumn. The models may underestimate the observed boundary layer-to-free troposphere CO₂ differences in spring and autumn due to model errors in boundary layer height. Attribution of the causes of model biases in other seasons remains elusive. Transport errors, prior fluxes, and/or inversion algorithms appear to be the primary cause of these biases since model performance is not highly sensitive to the CO₂ data used in the inversion. The metrics presented here provide new benchmarks regarding the ability of atmospheric inversion systems to reproduce the CO₂ structure of mid-latitude weather systems. Controlled experiments are needed to link these metrics more directly to the accuracy of regional or global flux estimates.

Published
2022

47. A new exponentially decaying error correlation model for assimilating OCO-2 column-average CO2 data using a length scale computed from airborne lidar measurements

Author

Baker, David F., Bell, Emily, Davis, Kenneth J., Campbell, Joel F., Lin, Bing, and Dobler, Jeremy

Abstract

To check the accuracy of column-average dry air CO2 mole fractions (XCO2) retrieved from Orbiting Carbon Observatory (OCO-2) data, a similar quantity has been measured from the Multi-functional Fiber Laser Lidar (MFLL) aboard aircraft flying underneath OCO-2 as part of the Atmospheric Carbon and Transport (ACT) – America flight campaigns. Here we do a lagged correlation analysis of these MFLL–OCO-2 column CO2 differences and find that their correlation spectrum falls off rapidly at along-track separation distances under 10 km, with a correlation length scale of about 10 km, and less rapidly at longer separation distances, with a correlation length scale of about 20 km. The OCO-2 satellite takes many CO2 measurements with small (∼3 km2) fields of view (FOVs) in a thin ( km wide) swath running parallel to its orbit: up to 24 separate FOVs may be obtained per second (across a ∼6.75 km distance on the ground), though clouds, aerosols, and other factors cause considerable data dropout. Errors in the CO2 retrieval method have long been thought to be correlated at these fine scales, and methods to account for these when assimilating these data into top-down atmospheric CO2 flux inversions have been developed. A common approach has been to average the data at coarser scales (e.g., in 10 s long bins) along-track, then assign an uncertainty to the averaged value that accounts for the error correlations. Here we outline the methods used up to now for computing these 10 s averages and their uncertainties, including the constant-correlation-with-distance error model that was used to summarize the OCO-2 version 9 XCO2 retrievals as part of the OCO-2 flux inversion model intercomparison project. We then derive a new one-dimensional error model using correlations that decay exponentially with separation distance, apply this model to the OCO-2 data using the correlation length scales derived from the MFLL–OCO-2 differences, and compare the results (for both the average and its uncertainty) to those given by the current constant correlation error model. To implement this new model, the data are averaged first across 2 s spans to collapse the cross-track distribution of the real data onto the 1-D path assumed by the new model. Considering correlated errors can cause the average value to fall outside the range of the values averaged; two strategies for preventing this are presented. The correlation lengths over the ocean, which the land-based MFLL data do not clarify, are assumed to be twice those over the land. The new correlation model gives 10 s XCO2 averages that are only a few tenths of 1 ppm different from the constant correlation model. Over land, the uncertainties in the mean are also similar, suggesting that the +0.3 constant correlation coefficient currently used in the model there is accurate. Over the oceans, the twice-the-land correlation lengths that we assume here result in a significantly lower uncertainty on the mean than the +0.6 constant correlation currently gives – measurements similar to the MFLL ones are needed over the oceans to do better. Finally, we show how our 1-D exponential error correlation model may be used to account for correlations in inversion methods that choose to assimilate each XCO2 retrieval individually and also to account for correlations between separate 10 s averages when these are assimilated instead.

Published
2022

48. Space-based active optical remote sensing of carbon dioxide column using high-energy two-micron pulsed ipda lidar

Author

Singh Upendra N., Refaat Tamer F., Ismail Syed, Petros Mulugeta, Davis Kenneth J., Kawa Stephan R., and Menzies Robert T.

Subjects
Physics, QC1-999
Abstract

Modeling of a space-based high-energy 2-μm triple-pulse Integrated Path Differential Absorption (IPDA) lidar was conducted to demonstrate carbon dioxide (CO2) measurement capability and to evaluate random and systematic errors. A high pulse energy laser and an advanced MCT e-APD detector were incorporated in this model. Projected performance shows 0.5 ppm precision and 0.3 ppm bias in low-tropospheric column CO2 mixing ratio measurements from space for 10 second signal averaging over Railroad Valley (RRV) reference surface.

Published
2018
Full Text
View/download PDF

49. Development of an advanced Two-Micron triple-pulse IPDA lidar for carbon dioxide and water vapor measurements

Author

Petros Mulugeta, Refaat Tamer F., Singh Upendra N., Yu Jirong, Antill Charles, Remus Ruben, Taylor Bryant D., Wong Teh-Hwa, Reithmaier Karl, Lee Jane, Ismail Syed, and Davis Kenneth J

Subjects
Physics, QC1-999
Abstract

An advanced airborne triple-pulse 2-μm integrated path differential absorption (IPDA) lidar is under development at NASA Langley Research Center that targets both carbon dioxide (CO2) and water vapor (H2O) measurements simultaneously and independently. This lidar is an upgrade to the successfully demonstrated CO2 2-μm double-pulse IPDA. Upgrades include high-energy, highrepetition rate 2-μm triple-pulse laser transmitter, innovative wavelength control and advanced HgCdTe (MCT) electron-initiated avalanche photodiode detection system. Ground testing and airborne validation plans are presented.

Published
2018
Full Text
View/download PDF

50. Technology Advancements for Active Remote Sensing of Carbon Dioxide from Space using the Active Sensing of CO2 Emissions over Nights, Days, and Seasons (ASCENDS) CarbonHawk Experiment Simulator

Author

Obland Michael D., Campbell Joel, Kooi Susan, Fan Tai-Fang, Carrion William, Hicks Jonathan, Lin Bing, Nehrir Amin R., Browell Edward V., Meadows Byron, and Davis Kenneth J.

Subjects
Physics, QC1-999
Abstract

This work describes advances in critical lidar technologies and techniques developed as part of the NASA Active Sensing of CO2 Emissions over Nights, Days, and Seasons CarbonHawk Experiment Simulator system for measuring atmospheric column carbon dioxide (CO2) mixing ratios. This work provides an overview of these technologies and results from recent test flights during the NASA Atmospheric Carbon and Transport – America (ACT-America) Earth Venture Suborbital summer 2016 flight campaign.

Published
2018
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results