Your search keyword '"Butterfield, Z."' showing total 5 results

1. Contrasting Regional Carbon Cycle Responses to Seasonal Climate Anomalies Across the East-West Divide of Temperate North America.

Author

Byrne, B, Liu, J, Bloom, AA, Bowman, KW, Butterfield, Z, Joiner, J, Keenan, TF, Keppel-Aleks, G, Parazoo, NC, and Yin, Y

Subjects

North America, carbon cycle, gross primary production, interannual variability, net ecosystem exchange, terrestrial biosphere model, Atmospheric Sciences, Geochemistry, Oceanography, Meteorology & Atmospheric Sciences

Abstract

Across temperate North America, interannual variability (IAV) in gross primary production (GPP) and net ecosystem exchange (NEE) and their relationship with environmental drivers are poorly understood. Here, we examine IAV in GPP and NEE and their relationship to environmental drivers using two state-of-the-science flux products: NEE constrained by surface and space-based atmospheric CO2 measurements over 2010-2015 and satellite up-scaled GPP from FluxSat over 2001-2017. We show that the arid western half of temperate North America provides a larger contribution to IAV in GPP (104% of east) and NEE (127% of east) than the eastern half, in spite of smaller magnitude of annual mean GPP and NEE. This occurs because anomalies in western ecosystems are temporally coherent across the growing season leading to an amplification of GPP and NEE. In contrast, IAV in GPP and NEE in eastern ecosystems is dominated by seasonal compensation effects, associated with opposite responses to temperature anomalies in spring and summer. Terrestrial biosphere models in the MsTMIP ensemble generally capture these differences between eastern and western temperate North America, although there is considerable spread between models.

Published

2020

2. Airborne measurements of western U.S. wildfire emissions: Comparison with prescribed burning and air quality implications

Author

Liu, X, Huey, LG, Yokelson, RJ, Selimovic, V, Simpson, IJ, Müller, M, Jimenez, JL, Campuzano-Jost, P, Beyersdorf, AJ, Blake, DR, Butterfield, Z, Choi, Y, Crounse, JD, Day, DA, Diskin, GS, Dubey, MK, Fortner, E, Hanisco, TF, Hu, W, King, LE, Kleinman, L, Meinardi, S, Mikoviny, T, Onasch, TB, Palm, BB, Peischl, J, Pollack, IB, Ryerson, TB, Sachse, GW, Sedlacek, AJ, Shilling, JE, Springston, S, St. Clair, JM, Tanner, DJ, Teng, AP, Wennberg, PO, Wisthaler, A, and Wolfe, GM

Subjects

Wildfire emission, Air quality, Emission factor, Fine particulate matter, Meteorology & Atmospheric Sciences

Abstract

Wildfires emit significant amounts of pollutants that degrade air quality. Plumes from three wildfires in the western U.S. were measured from aircraft during the Studies of Emissions and Atmospheric Composition, Clouds and Climate Coupling by Regional Surveys (SEAC4RS) and the Biomass Burning Observation Project (BBOP), both in summer 2013. This study reports an extensive set of emission factors (EFs) for over 80 gases and 5 components of submicron particulate matter (PM1) from these temperate wildfires. These include rarely, or never before, measured oxygenated volatile organic compounds and multifunctional organic nitrates. The observed EFs are compared with previous measurements of temperate wildfires, boreal forest fires, and temperate prescribed fires. The wildfires emitted high amounts of PM1 (with organic aerosol (OA) dominating the mass) with an average EF that is more than 2 times the EFs for prescribed fires. The measured EFs were used to estimate the annual wildfire emissions of carbon monoxide, nitrogen oxides, total nonmethane organic compounds, and PM1 from 11 western U.S. states. The estimated gas emissions are generally comparable with the 2011 National Emissions Inventory (NEI). However, our PM1 emission estimate (1530 ± 570 Gg yr-1) is over 3 times that of the NEI PM2.5 estimate and is also higher thanthe PM2.5 emitted from all other sources in these states in the NEI. This study indicates that the source of OA from biomass burning in the western states is significantly underestimated. In addition, our results indicate that prescribed burning may be an effective method to reduce fine particle emissions.

Published

2017

3. Signature of a tropical Pacific cyclone in the composition of the upper troposphere over Socorro, NM

Author

Minschwaner, K., primary, Manney, G. L., additional, Petropavlovskikh, I., additional, Torres, L. A., additional, Lawrence, Z. D., additional, Sutherland, B., additional, Thompson, A. M., additional, Johnson, B. J., additional, Butterfield, Z., additional, Dubey, M. K., additional, Froidevaux, L., additional, Lambert, A., additional, Read, W. G., additional, and Schwartz, M. J., additional

Published

2015

4. Interannual and Seasonal Drivers of Carbon Cycle Variability Represented by the Community Earth System Model (CESM2).

Author

Wieder WR, Butterfield Z, Lindsay K, Lombardozzi DL, and Keppel-Aleks G

Abstract

Earth system models are intended to make long-term projections, but they can be evaluated at interannual and seasonal time scales. Although the Community Earth System Model (CESM2) showed improvements in a number of terrestrial carbon cycle benchmarks, relative to its predecessor, our analysis suggests that the interannual variability (IAV) in net terrestrial carbon fluxes did not show similar improvements. The model simulated low IAV of net ecosystem production (NEP), resulting in a weaker than observed sensitivity of the carbon cycle to climate variability. Low IAV in net fluxes likely resulted from low variability in gross primary productivity (GPP)-especially in the tropics-and a high covariation between GPP and ecosystem respiration. Although lower than observed, the IAV of NEP had significant climate sensitivities, with positive NEP anomalies associated with warmer and drier conditions in high latitudes, and with wetter and cooler conditions in mid and low latitudes. We identified two dominant modes of seasonal variability in carbon cycle flux anomalies in our fully coupled CESM2 simulations that are characterized by seasonal amplification and redistribution of ecosystem fluxes. Seasonal amplification of net and gross carbon fluxes showed climate sensitivities mirroring those of annual fluxes. Seasonal redistribution of carbon fluxes is initiated by springtime temperature anomalies, but subsequently negative feedbacks in soil moisture during the summer and fall result in net annual carbon losses from land. These modes of variability are also seen in satellite proxies of GPP, suggesting that CESM2 appropriately represents regional sensitivities of photosynthesis to climate variability on seasonal time scales., Competing Interests: The authors declare no conflicts of interest relevant to this study., (© 2021. The Authors.)

Published

2021

5. Regional Influence of Aerosol Emissions from Wildfires Driven by Combustion Efficiency: Insights from the BBOP Campaign.

Author

Collier S, Zhou S, Onasch TB, Jaffe DA, Kleinman L, Sedlacek AJ 3rd, Briggs NL, Hee J, Fortner E, Shilling JE, Worsnop D, Yokelson RJ, Parworth C, Ge X, Xu J, Butterfield Z, Chand D, Dubey MK, Pekour MS, Springston S, and Zhang Q

Subjects

Biomass, Oregon, Aerosols analysis, Air Pollutants analysis, Environmental Monitoring, Fires

Abstract

Wildfires are important contributors to atmospheric aerosols and a large source of emissions that impact regional air quality and global climate. In this study, the regional and nearfield influences of wildfire emissions on ambient aerosol concentration and chemical properties in the Pacific Northwest region of the United States were studied using real-time measurements from a fixed ground site located in Central Oregon at the Mt. Bachelor Observatory (∼2700 m a.s.l.) as well as near their sources using an aircraft. The regional characteristics of biomass burning aerosols were found to depend strongly on the modified combustion efficiency (MCE), an index of the combustion processes of a fire. Organic aerosol emissions had negative correlations with MCE, whereas the oxidation state of organic aerosol increased with MCE and plume aging. The relationships between the aerosol properties and MCE were consistent between fresh emissions (∼1 h old) and emissions sampled after atmospheric transport (6-45 h), suggesting that biomass burning organic aerosol concentration and chemical properties were strongly influenced by combustion processes at the source and conserved to a significant extent during regional transport. These results suggest that MCE can be a useful metric for describing aerosol properties of wildfire emissions and their impacts on regional air quality and global climate.

Published

2016