Your search keyword '"WOFSY, STEVEN C."' showing total 44 results

1. Methane point source quantification using MethaneAIR: a new airborne imaging spectrometer

Author

Chulakadabba, Apisada, Sargent, Maryann, Lauvaux, Thomas, Benmergui, Joshua S, Franklin, Jonathan E, Miller, Christopher Chan, Wilzewski, Jonas S, Roche, Sébastien, Conway, Eamon, Souri, Amir H, Sun, Kang, Luo, Bingkun, Hawthrone, Jacob, Samra, Jenna, Daube, Bruce C, Liu, Xiong, Chance, Kelly, Li, Yang, Gautam, Ritesh, Omara, Mark, Rutherford, Jeff S, Sherwin, Evan D, Brandt, Adam, and Wofsy, Steven C

Subjects

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

Abstract

The MethaneSAT satellite instrument and its aircraft precursor, MethaneAIR, are imaging spectrometers designed to measure methane concentrations with wide spatial coverage, fine spatial resolution, and high precision compared to currently deployed remote sensing instruments. At 12 960 m cruise altitude above ground (13 850 m above sea level), MethaneAIR datasets have a 4.5 km swath gridded to 10 m × 10 m pixels with 17-20 ppb standard deviation on a flat scene. MethaneAIR was deployed in the summer of 2021 in the Permian Basin to test the accuracy of the retrieved methane concentrations and emission rates using the algorithms developed for MethaneSAT. We report here point source emissions obtained during a single-blind volume-controlled release experiment, using two methods. (1) The modified integrated mass enhancement (mIME) method estimates emission rates using the total mass enhancement of methane in an observed plume combined with winds obtained from Weather Research Forecast driven by High-Resolution Rapid Refresh meteorological data in Large Eddy Simulations mode (WRF-LES-HRRR). WRF-LES-HRRR simulates winds in stochastic eddy-scale (100-1000 m) variability, which is particularly important for low-wind conditions and informing the error budget. The mIME can estimate emission rates of plumes of any size that are detectable by MethaneAIR. (2) The divergence integral (DI) method applies Gauss's theorem to estimate the flux divergence fields through a series of closed surfaces enclosing the sources. The set of boxes grows from the upwind side of the plume through the core of each plume and downwind. No selection of inflow concentration, as used in the mIME, is required. The DI approach can efï¬ ciently determine ï¬ uxes from large sources and clusters of sources but cannot resolve small point emissions. These methods account for the effects of eddy-scale variation in different ways: The DI averages across many eddies, whereas the mIME re-samples many eddies from the LES simulation. The DI directly uses HRRR winds, while mIME uses WRF-LES-HRRR wind products. Emissions estimates from both the mIME and DI methods agreed closely with the single-blind volume-controlled experiments (N Combining double low line 21). The York regression between the estimated emissions and the released emissions has a slope of 0.96 [0.84, 1.08], R Combining double low line 0.83 and N Combining double low line 21, with 30 % mean percentage error for the whole dataset, which indicates that MethaneAIR can quantify point sources emitting more than 200 kg h-1 for the mIME and 500 kg h-1 for the DI method. The two methods also agreed on methane emission estimates from various uncontrolled sources in the Permian Basin. The experiment thus demonstrates the powerful potential of the MethaneAIR instrument and suggests that the quantification method should be transferable to MethaneSAT if it meets the design specifications.

Published

2023

2. Asymmetric response of Amazon forest water and energy fluxes to wet and dry hydrological extremes reveals onset of a local drought‐induced tipping point

Author

Restrepo‐Coupe, Natalia, Christoffersen, Bradley O’Donnell, Longo, Marcos, Alves, Luciana F, Campos, Kleber Silva, da Araujo, Alessandro C, de Oliveira, Raimundo C, Prohaska, Neill, da Silva, Rodrigo, Tapajos, Raphael, Wiedemann, Kenia T, Wofsy, Steven C, and Saleska, Scott R

Subjects

Earth Sciences, Biological Sciences, Ecology, Climate Action, Amazonia, ecosystem-climate interactions, Eddy covariance, ENSO, tropical forests, water and energy flux seasonality, Environmental Sciences, Biological sciences, Earth sciences, Environmental sciences

Abstract

Understanding the effects of intensification of Amazon basin hydrological cycling-manifest as increasingly frequent floods and droughts-on water and energy cycles of tropical forests is essential to meeting the challenge of predicting ecosystem responses to climate change, including forest "tipping points". Here, we investigated the impacts of hydrological extremes on forest function using 12+ years of observations (between 2001-2020) of water and energy fluxes from eddy covariance, along with associated ecological dynamics from biometry, at the Tapajós National Forest. Measurements encompass the strong 2015-2016 El Niño drought and La Niña 2008-2009 wet events. We found that the forest responded strongly to El Niño-Southern Oscillation (ENSO): Drought reduced water availability for evapotranspiration (ET) leading to large increases in sensible heat fluxes (H). Partitioning ET by an approach that assumes transpiration (T) is proportional to photosynthesis, we found that water stress-induced reductions in canopy conductance (Gs ) drove T declines partly compensated by higher evaporation (E). By contrast, the abnormally wet La Niña period gave higher T and lower E, with little change in seasonal ET. Both El Niño-Southern Oscillation (ENSO) events resulted in changes in forest structure, manifested as lower wet-season leaf area index. However, only during El Niño 2015-2016, we observed a breakdown in the strong meteorological control of transpiration fluxes (via energy availability and atmospheric demand) because of slowing vegetation functions (via shutdown of Gs and significant leaf shedding). Drought-reduced T and Gs , higher H and E, amplified by feedbacks with higher temperatures and vapor pressure deficits, signaled that forest function had crossed a threshold, from which it recovered slowly, with delay, post-drought. Identifying such tipping point onsets (beyond which future irreversible processes may occur) at local scale is crucial for predicting basin-scale threshold-crossing changes in forest energy and water cycling, leading to slow-down in forest function, potentially resulting in Amazon forests shifting into alternate degraded states.

Published

2023

3. Heterogeneity and chemical reactivity of the remote troposphere defined by aircraft measurements – corrected

Author

Guo, Hao, Flynn, Clare M, Prather, Michael J, Strode, Sarah A, Steenrod, Stephen D, Emmons, Louisa, Lacey, Forrest, Lamarque, Jean-Francois, Fiore, Arlene M, Correa, Gus, Murray, Lee T, Wolfe, Glenn M, St. Clair, Jason M, Kim, Michelle, Crounse, John, Diskin, Glenn, DiGangi, Joshua, Daube, Bruce C, Commane, Roisin, McKain, Kathryn, Peischl, Jeff, Ryerson, Thomas B, Thompson, Chelsea, Hanisco, Thomas F, Blake, Donald, Blake, Nicola J, Apel, Eric C, Hornbrook, Rebecca S, Elkins, James W, Hintsa, Eric J, Moore, Fred L, and Wofsy, Steven C

Subjects

Climate Action, Astronomical and Space Sciences, Atmospheric Sciences, Meteorology & Atmospheric Sciences

Abstract

The NASA Atmospheric Tomography (ATom) mission built a photochemical climatology of air parcels based on in situ measurements with the NASA DC-8 aircraft along objectively planned profiling transects through the middle of the Pacific and Atlantic oceans. In this paper we present and analyze a data set of 10s (2km) merged and gap-filled observations of the key reactive species driving the chemical budgets of O3 and CH4 (O3, CH4, CO, H2O, HCHO, H2O2, CH3OOH, C2H6, higher alkanes, alkenes, aromatics, NOx, HNO3, HNO4, peroxyacetyl nitrate, and other organic nitrates), consisting of 146494 distinct air parcels from ATom deployments 1 through 4. Six models calculated the O3 and CH4 photochemical tendencies from this modeling data stream for ATom 1. We find that 80%-90% of the total reactivity lies in the top 50% of the parcels and 25%-35% in the top 10%, supporting previous model-only studies that tropospheric chemistry is driven by a fraction of all the air. Surprisingly, the probability densities of species and reactivities averaged on a model scale (100 km) differ only slightly from the 2km ATom 10s data, indicating that much of the heterogeneity in tropospheric chemistry can be captured with current global chemistry models. Comparing the ATom reactivities over the tropical oceans with climatological statistics from six global chemistry models, we find generally good agreement with the reactivity rates for O3 and CH4. Models distinctly underestimate O3 production below 2km relative to the mid-troposphere, and this can be traced to lower NOx levels than observed. Attaching photochemical reactivities to measurements of chemical species allows for a richer, yet more constrained-to-what-matters, set of metrics for model evaluation. This paper presents a corrected version of the paper published under the same authors and title (sans "corrected") as 10.5194/acp-21-13729-2021.

Published

2023

4. 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

5. Earlier snowmelt may lead to late season declines in plant productivity and carbon sequestration in Arctic tundra ecosystems

Author

Zona, Donatella, Lafleur, Peter M, Hufkens, Koen, Bailey, Barbara, Gioli, Beniamino, Burba, George, Goodrich, Jordan P, Liljedahl, Anna K, Euskirchen, Eugénie S, Watts, Jennifer D, Farina, Mary, Kimball, John S, Heimann, Martin, Göckede, Mathias, Pallandt, Martijn, Christensen, Torben R, Mastepanov, Mikhail, López-Blanco, Efrén, Jackowicz-Korczynski, Marcin, Dolman, Albertus J, Marchesini, Luca Belelli, Commane, Roisin, Wofsy, Steven C, Miller, Charles E, Lipson, David A, Hashemi, Josh, Arndt, Kyle A, Kutzbach, Lars, Holl, David, Boike, Julia, Wille, Christian, Sachs, Torsten, Kalhori, Aram, Song, Xia, Xu, Xiaofeng, Humphreys, Elyn R, Koven, Charles D, Sonnentag, Oliver, Meyer, Gesa, Gosselin, Gabriel H, Marsh, Philip, and Oechel, Walter C

Subjects

Biological Sciences, Ecology, Life on Land, Arctic Regions, Carbon Dioxide, Carbon Sequestration, Climate Change, Ecosystem, Plants, Seasons, Soil, Tundra

Abstract

Arctic warming is affecting snow cover and soil hydrology, with consequences for carbon sequestration in tundra ecosystems. The scarcity of observations in the Arctic has limited our understanding of the impact of covarying environmental drivers on the carbon balance of tundra ecosystems. In this study, we address some of these uncertainties through a novel record of 119 site-years of summer data from eddy covariance towers representing dominant tundra vegetation types located on continuous permafrost in the Arctic. Here we found that earlier snowmelt was associated with more tundra net CO2 sequestration and higher gross primary productivity (GPP) only in June and July, but with lower net carbon sequestration and lower GPP in August. Although higher evapotranspiration (ET) can result in soil drying with the progression of the summer, we did not find significantly lower soil moisture with earlier snowmelt, nor evidence that water stress affected GPP in the late growing season. Our results suggest that the expected increased CO2 sequestration arising from Arctic warming and the associated increase in growing season length may not materialize if tundra ecosystems are not able to continue sequestering CO2 later in the season.

Published

2022

6. Carbon budget of the Harvard Forest Long‐Term Ecological Research site: pattern, process, and response to global change

Author

Finzi, Adrien C, Giasson, Marc‐André, Plotkin, Audrey A Barker, Aber, John D, Boose, Emery R, Davidson, Eric A, Dietze, Michael C, Ellison, Aaron M, Frey, Serita D, Goldman, Evan, Keenan, Trevor F, Melillo, Jerry M, Munger, J William, Nadelhoffer, Knute J, Ollinger, Scott V, Orwig, David A, Pederson, Neil, Richardson, Andrew D, Savage, Kathleen, Tang, Jianwu, Thompson, Jonathan R, Williams, Christopher A, Wofsy, Steven C, Zhou, Zaixing, and Foster, David R

Subjects

Life on Land, belowground production, carbon cycling, climate change, disturbance, ecosystem ecology, eddy covariance, forest ecosystems, gross primary production, long-term ecological research, net primary production, permanent plots, Physical Geography and Environmental Geoscience, Ecological Applications, Ecology

Abstract

How, where, and why carbon (C) moves into and out of an ecosystem through time are long-standing questions in biogeochemistry. Here, we bring together hundreds of thousands of C-cycle observations at the Harvard Forest in central Massachusetts, USA, a mid-latitude landscape dominated by 80–120-yr-old closed-canopy forests. These data answered four questions: (1) where and how much C is presently stored in dominant forest types; (2) what are current rates of C accrual and loss; (3) what biotic and abiotic factors contribute to variability in these rates; and (4) how has climate change affected the forest’s C cycle? Harvard Forest is an active C sink resulting from forest regrowth following land abandonment. Soil and tree biomass comprise nearly equal portions of existing C stocks. Net primary production (NPP) averaged 680–750 g C·m−2·yr−1; belowground NPP contributed 38–47% of the total, but with large uncertainty. Mineral soil C measured in the same inventory plots in 1992 and 2013 was too heterogeneous to detect change in soil-C pools; however, radiocarbon data suggest a small but persistent sink of 10–30 g C·m−2·yr−1. Net ecosystem production (NEP) in hardwood stands averaged ~300 g C·m−2·yr−1. NEP in hemlock-dominated forests averaged ~450 g C·m−2·yr−1 until infestation by the hemlock woolly adelgid turned these stands into a net C source. Since 2000, NPP has increased by 26%. For the period 1992–2015, NEP increased 93%. The increase in mean annual temperature and growing season length alone accounted for ~30% of the increase in productivity. Interannual variations in GPP and NEP were also correlated with increases in red oak biomass, forest leaf area, and canopy-scale light-use efficiency. Compared to long-term global change experiments at the Harvard Forest, the C sink in regrowing biomass equaled or exceeded C cycle modifications imposed by soil warming, N saturation, and hemlock removal. Results of this synthesis and comparison to simulation models suggest that forests across the region are likely to accrue C for decades to come but may be disrupted if the frequency or severity of biotic and abiotic disturbances increases.

Published

2020

7. Gravitational separation of Ar/N-2 and age of air in the lowermost stratosphere in airborne observations and a chemical transport model

Author

Birner, Benjamin, Chipperfield, Martyn P, Morgan, Eric J, Stephens, Britton B, Linz, Marianna, Feng, Wuhu, Wilson, Chris, Bent, Jonathan D, Wofsy, Steven C, Severinghaus, Jeffrey, and Keeling, Ralph F

Subjects

Astronomical and Space Sciences, Atmospheric Sciences, Meteorology & Atmospheric Sciences

Abstract

Abstract. Accurate simulation of atmospheric circulation,particularly in the lower stratosphere, is challenging due to unresolvedwave–mean flow interactions and limited high-resolution observations for validation. Gravity-induced pressure gradients lead to a small butmeasurable separation of heavy and light gases by molecular diffusion in thestratosphere. Because the relative abundance of Ar to N2 is exclusivelycontrolled by physical transport, the argon-to-nitrogen ratio (Ar∕N2)provides an additional constraint on circulation and the age of air (AoA),i.e., the time elapsed since entry of an air parcel into the stratosphere. Here we use airborne measurements of N2O and Ar∕N2 from ninecampaigns with global coverage spanning 2008–2018 to calculate AoA and toquantify gravitational separation in the lowermost stratosphere. To thisend, we develop a new N2O–AoA relationship using a Markov chain Monte Carlo algorithm. We observe that gravitational separation increases systematically with increasing AoA for samples with AoA between 0 and 3 years. These observations are compared to a simulation of the TOMCAT/SLIMCAT 3-D chemical transport model, which has been updated to includegravitational fractionation of gases. We demonstrate that although AoA atold ages is slightly underestimated in the model, the relationship betweenAr∕N2 and AoA is robust and agrees with the observations. Thishighlights the potential of Ar∕N2 to become a new AoA tracer that is subject only to physical transport phenomena and can supplement the suite of available AoA indicators.

Published

2020

8. Gravitational separation of Ar/N2 and age of air in the lowermost stratosphere in airborne observations and a chemical transport model

Author

Birner, Benjamin, Chipperfield, Martyn P, Morgan, Eric J, Stephens, Britton B, Linz, Marianna, Feng, Wuhu, Wilson, Chris, Bent, Jonathan D, Wofsy, Steven C, Severinghaus, Jeffrey, and Keeling, Ralph F

Abstract

Abstract. Accurate simulation of atmospheric circulation, particularly in the lower stratosphere, is challenging due to unresolved wave-mean flow interactions and limited high-resolution observations for validation. Gravity-induced pressure gradients lead to a small but measurable separation of heavy and light gases by molecular diffusion in the stratosphere. Because the relative abundance of Ar to N2 is exclusively controlled by physical transport, the argon-to-nitrogen ratio (Ar/N2) provides an additional constraint on circulation and the age of air (AoA), i.e. the time elapsed since entry of an air parcel into the stratosphere. Here we use airborne measurements of N2O and Ar/N2 from nine campaigns with global coverage spanning 2008–2018 to calculate AoA and to quantify gravitational separation in the lowermost stratosphere. To this end, we develop a new N2O-AoA relationship using a Markov Chain Monte Carlo algorithm. We observe that gravitational separation increases systematically with increasing AoA for samples with AoA between 0 to 3 years. These observations are compared to a simulation of the TOMCAT/SLIMCAT 3-D chemical transport model, which has been updated to include gravitational fractionation of gases. We demonstrate that although AoA at old ages is slightly underestimated in the model, the relationship between Ar/N2 and AoA is robust and agrees with the observations. This highlights the potential of Ar/N2 to become a new AoA tracer that is subject only to physical transport phenomena and can supplement the suite of available AoA indicators.

Published

2020

9. The biophysics, ecology, and biogeochemistry of functionally diverse, vertically and horizontally heterogeneous ecosystems: the Ecosystem Demography model, version 2.2 – Part 1: Model description

Author

Longo, Marcos, Knox, Ryan G, Medvigy, David M, Levine, Naomi M, Dietze, Michael C, Kim, Yeonjoo, Swann, Abigail LS, Zhang, Ke, Rollinson, Christine R, Bras, Rafael L, Wofsy, Steven C, and Moorcroft, Paul R

Subjects

Earth Sciences

Abstract

Earth system models (ESMs) have been developed to represent the role of terrestrial ecosystems on the energy, water, and carbon cycles. However, many ESMs still lack representation of within-ecosystem heterogeneity and diversity. In this paper, we present the Ecosystem Demography model version 2.2 (ED-2.2). In ED-2.2, the biophysical and physiological processes account for the horizontal and vertical heterogeneity of the ecosystem: The energy, water, and carbon cycles are solved separately for a series of vegetation cohorts (groups of individual plants of similar size and plant functional type) distributed across a series of spatially implicit patches (representing collections of microenvironments that have a similar disturbance history).We define the equations that describe the energy, water, and carbon cycles in terms of total energy, water, and carbon, which simplifies the differential equations and guarantees excellent conservation of these quantities in long-term simulation (

Published

2019

10. The biophysics, ecology, and biogeochemistry of functionally diverse, vertically and horizontally heterogeneous ecosystems: the Ecosystem Demography model, version 2.2 – Part 2: Model evaluation for tropical South America

Author

Longo, Marcos, Knox, Ryan G, Levine, Naomi M, Swann, Abigail LS, Medvigy, David M, Dietze, Michael C, Kim, Yeonjoo, Zhang, Ke, Bonal, Damien, Burban, Benoit, Camargo, Plínio B, Hayek, Matthew N, Saleska, Scott R, da Silva, Rodrigo, Bras, Rafael L, Wofsy, Steven C, and Moorcroft, Paul R

Subjects

Affordable and Clean Energy, Life Below Water, Earth Sciences

Abstract

The Ecosystem Demography model version 2.2 (ED-2.2) is a terrestrial biosphere model that simulates the biophysical, ecological, and biogeochemical dynamics of vertically and horizontally heterogeneous terrestrial ecosystems. In a companion paper (Longo et al., 2019a), we described how the model solves the energy, water, and carbon cycles, and verified the high degree of conservation of these properties in long-term simulations that include long-term (multi-decadal) vegetation dynamics. Here, we present a detailed assessment of the model's ability to represent multiple processes associated with the biophysical and biogeochemical cycles in Amazon forests. We use multiple measurements from eddy covariance towers, forest inventory plots, and regional remote-sensing products to assess the model's ability to represent biophysical, physiological, and ecological processes at multiple timescales, ranging from subdaily to century long. The ED-2.2 model accurately describes the vertical distribution of light, water fluxes, and the storage of water, energy, and carbon in the canopy air space, the regional distribution of biomass in tropical South America, and the variability of biomass as a function of environmental drivers. In addition, ED-2.2 qualitatively captures several emergent properties of the ecosystem found in observations, specifically observed relationships between aboveground biomass, mortality rates, and wood density; however, the slopes of these relationships were not accurately captured. We also identified several limitations, including the model's tendency to overestimate the magnitude and seasonality of heterotrophic respiration and to overestimate growth rates in a nutrient-poor tropical site. The evaluation presented here highlights the potential of incorporating structural and functional heterogeneity within biomes in Earth system models (ESMs) and to realistically represent their impacts on energy, water, and carbon cycles. We also identify several priorities for further model development.

Published

2019

11. Atmospheric Acetaldehyde: Importance of Air‐Sea Exchange and a Missing Source in the Remote Troposphere

Author

Wang, Siyuan, Hornbrook, Rebecca S, Hills, Alan, Emmons, Louisa K, Tilmes, Simone, Lamarque, Jean‐François, Jimenez, Jose L, Campuzano‐Jost, Pedro, Nault, Benjamin A, Crounse, John D, Wennberg, Paul O, Kim, Michelle, Allen, Hannah, Ryerson, Thomas B, Thompson, Chelsea R, Peischl, Jeff, Moore, Fred, Nance, David, Hall, Brad, Elkins, James, Tanner, David, Huey, L Gregory, Hall, Samuel R, Ullmann, Kirk, Orlando, John J, Tyndall, Geoff S, Flocke, Frank M, Ray, Eric, Hanisco, Thomas F, Wolfe, Glenn M, St. Clair, Jason, Commane, Róisín, Daube, Bruce, Barletta, Barbara, Blake, Donald R, Weinzierl, Bernadett, Dollner, Maximilian, Conley, Andrew, Vitt, Francis, Wofsy, Steven C, Riemer, Daniel D, and Apel, Eric C

Subjects

Climate Action, Meteorology & Atmospheric Sciences

Abstract

We report airborne measurements of acetaldehyde (CH3CHO) during the first and second deployments of the National Aeronautics and Space Administration (NASA) Atmospheric Tomography Mission (ATom). The budget of CH3CHO is examined using the Community Atmospheric Model with chemistry (CAM-chem), with a newly-developed online air-sea exchange module. The upper limit of the global ocean net emission of CH3CHO is estimated to be 34 Tg a-1 (42 Tg a-1 if considering bubble-mediated transfer), and the ocean impacts on tropospheric CH3CHO are mostly confined to the marine boundary layer. Our analysis suggests that there is an unaccounted CH3CHO source in the remote troposphere and that organic aerosols can only provide a fraction of this missing source. We propose that peroxyacetic acid (PAA) is an ideal indicator of the rapid CH3CHO production in the remote troposphere. The higher-than-expected CH3CHO measurements represent a missing sink of hydroxyl radicals (and halogen radical) in current chemistry-climate models.

Published

2019

12. The biophysics, ecology, and biogeochemistry of functionally diverse, vertically- and horizontally-heterogeneous ecosystems: the Ecosystem Demography Model, version 2.2 – Part 2: Model evaluation

Author

Longo, Marcos, Knox, Ryan G, Levine, Naomi M, Swann, Abigail LS, Medvigy, David M, Dietze, Michael C, Kim, Yeonjoo, Zhang, Ke, Bonal, Damien, Burban, Benoit, Camargo, Plinio B, Hayek, Matthew N, Saleska, Scott R, da Silva, Rodrigo, Bras, Rafael L, Wofsy, Steven C, and Moorcroft, Paul R

Abstract

Abstract. The Ecosystem Demography Model version 2.2 (ED-2.2) is a terrestrial biosphere model that simulates the biophysical and biogeochemical cycles of dynamic ecosystems while considering the role of vertical structure of plant communities and the heterogeneity of such structures across the landscape. In a companion paper, we described in detail how the model solves the energy, water, and carbon cycles, and verified the excellent conservation of such properties in long-term simulation. Here, we present a thorough assessment of the model's ability to represent multiple processes associated with the biophysical and biogeochemical cycles, with focus on the Amazon forest. We used multiple measurements from eddy covariance towers, forest inventory plots and regional remote-sensing products to assess the model's ability to represent biophysical, physiological, and ecological processes at multiple time scales ranging from sub-daily to century-long. The ED-2.2 model accurately describes the vertical distribution of light, water fluxes and the storage of water, energy and carbon in the canopy air space, the regional distribution of biomass in tropical South America, and the variability of biomass as a function of environmental drivers. In addition, ED-2.2 also simulates emerging properties of the ecosystem found in observations, such as the relationship between biomass and mortality rates and wood density, although the relationships predicted by the model were biased. We also identified some of the model limitations, such as the model's tendency to overestimate the magnitude and seasonality of heterotrophic respiration, and to overestimate growth rates in a nutrient-poor tropical site. The evaluation presented here highlights the potential of incorporating structural and functional heterogeneity within biomes in ESMs, to realistically represent the role of forest structure and composition on energy, water, and carbon cycles, as well as the priority areas for further model development.

Published

2019

13. Carbon exchange in an Amazon forest: from hours to years

Author

Hayek, Matthew N, Longo, Marcos, Wu, Jin, Smith, Marielle N, Restrepo-Coupe, Natalia, Tapajós, Raphael, da Silva, Rodrigo, Fitzjarrald, David R, Camargo, Plinio B, Hutyra, Lucy R, Alves, Luciana F, Daube, Bruce, Munger, J William, Wiedemann, Kenia T, Saleska, Scott R, and Wofsy, Steven C

Subjects

Climate Action, Earth Sciences, Environmental Sciences, Biological Sciences, Meteorology & Atmospheric Sciences

Abstract

In Amazon forests, the relative contributions of climate, phenology, and disturbance to net ecosystem exchange of carbon (NEE) are not well understood. To partition influences across various timescales, we use a statistical model to represent eddy-covariance-derived NEE in an evergreen eastern Amazon forest as a constant response to changing meteorology and phenology throughout a decade. Our best fit model represented hourly NEE variations as changes due to sunlight, while seasonal variations arose from phenology influencing photosynthesis and from rainfall influencing ecosystem respiration, where phenology was asynchronous with dry-season onset. We compared annual model residuals with biometric forest surveys to estimate impacts of drought disturbance. We found that our simple model represented hourly and monthly variations in NEE well (R 2 Combining double low line 0.81 and 0.59, respectively). Modeled phenology explained 1 % of hourly and 26 % of monthly variations in observed NEE, whereas the remaining modeled variability was due to changes in meteorology. We did not find evidence to support the common assumption that the forest phenology was seasonally light- or water-triggered. Our model simulated annual NEE well, with the exception of 2002, the first year of our data record, which contained 1.2 MgC ha'1 of residual net emissions, because photosynthesis was anomalously low. Because a severe drought occurred in 1998, we hypothesized that this drought caused a persistent, multi-year depression of photosynthesis. Our results suggest drought can have lasting impacts on photosynthesis, possibly via partial damage to still-living trees.

Published

2018

14. Ecosystem heterogeneity and diversity mitigate Amazon forest resilience to frequent extreme droughts.

Author

Longo, Marcos, Knox, Ryan G, Levine, Naomi M, Alves, Luciana F, Bonal, Damien, Camargo, Plinio B, Fitzjarrald, David R, Hayek, Matthew N, Restrepo-Coupe, Natalia, Saleska, Scott R, da Silva, Rodrigo, Stark, Scott C, Tapajós, Raphael P, Wiedemann, Kenia T, Zhang, Ke, Wofsy, Steven C, and Moorcroft, Paul R

Subjects

Carbon Dioxide, Biomass, Rain, Plant Transpiration, Geography, Models, Theoretical, Computer Simulation, South America, Droughts, Forests, Amazon, biomass loss, climate change, droughts, ecosystem demography model, forest vulnerability, water and light competition, Models, Theoretical, Plant Biology & Botany, Biological Sciences, Agricultural and Veterinary Sciences

Abstract

The impact of increases in drought frequency on the Amazon forest's composition, structure and functioning remain uncertain. We used a process- and individual-based ecosystem model (ED2) to quantify the forest's vulnerability to increased drought recurrence. We generated meteorologically realistic, drier-than-observed rainfall scenarios for two Amazon forest sites, Paracou (wetter) and Tapajós (drier), to evaluate the impacts of more frequent droughts on forest biomass, structure and composition. The wet site was insensitive to the tested scenarios, whereas at the dry site biomass declined when average rainfall reduction exceeded 15%, due to high mortality of large-sized evergreen trees. Biomass losses persisted when year-long drought recurrence was shorter than 2-7 yr, depending upon soil texture and leaf phenology. From the site-level scenario results, we developed regionally applicable metrics to quantify the Amazon forest's climatological proximity to rainfall regimes likely to cause biomass loss > 20% in 50 yr according to ED2 predictions. Nearly 25% (1.8 million km2 ) of the Amazon forests could experience frequent droughts and biomass loss if mean annual rainfall or interannual variability changed by 2σ. At least 10% of the high-emission climate projections (CMIP5/RCP8.5 models) predict critically dry regimes over 25% of the Amazon forest area by 2100.

Published

2018

15. A novel correction for biases in forest eddy covariance carbon balance

Author

Hayek, Matthew N, Wehr, Richard, Longo, Marcos, Hutyra, Lucy R, Wiedemann, Kenia, Munger, J William, Bonal, Damien, Saleska, Scott R, Fitzjarrald, David R, and Wofsy, Steven C

Subjects

Life on Land, Carbon dioxide, Amazon, Eddy covariance, Forest carbon flux, Respiration, Friction velocity, Earth Sciences, Biological Sciences, Agricultural and Veterinary Sciences, Meteorology & Atmospheric Sciences

Abstract

Systematic biases in eddy covariance measurements of net ecosystem-atmosphere carbon dioxide exchange (NEE) are ubiquitous in forests when turbulence is low at night. We propose an alternative to the conventional bias correction, the friction velocity (u*) filter, by hypothesizing that these biases have two separate, concurrent causes: (1) a subcanopy CO₂ storage pool that eludes typical storage measurements, creating a turbulence-dependent bias, and (2) advective divergence loss of CO₂, creating a turbulence-independent bias. We correct for (1) using a simple parametric model of missing storage (MS). Prior experiments have inferred (2) directly from atmospheric measurements (DRAINO). For sites at which DRAINO experiments have not been performed or are infeasible, we estimate (2) empirically using a PAR-extrapolated advective respiration loss (PEARL) approach. We compare u* filter estimates of advection and NEE to MS-PEARL estimates at one temperate forest and two tropical forest sites.We find that for tropical forests, u* filters can produce a range of extreme NEE estimates, from long-term forest carbon emission to sequestration, that diverge from independent assessments and are not physically sustainable. Our MS model eliminates the dependence of nighttime NEE on u*, consistent with findings from DRAINO studies that nighttime advective losses of CO₂ are often not dependent on the strength of turbulence. Our PEARL estimates of mean advective loss agree with available DRAINO measurements. The MS-PEARL correction to long-term NEE produces better agreement with forest inventories at all three sites. Moreover, the correction retains all nighttime eddy covariance data and is therefore more widely applicable than the u* filter approach, which rejects substantial nighttime data—up to 93% at one of the tropical sites. The full MS-PEARL NEE correction is therefore an equally defensible and more practical alternative to the u* filter, but leads to different conclusions about the resulting carbon balance. Our results therefore highlight the need to investigate which approach’s underlying hypotheses are more physically realistic.

Published

2018

16. Carbon dioxide sources from Alaska driven by increasing early winter respiration from Arctic tundra

Author

Commane, Róisín, Lindaas, Jakob, Benmergui, Joshua, Luus, Kristina A, Chang, Rachel Y-W, Daube, Bruce C, Euskirchen, Eugénie S, Henderson, John M, Karion, Anna, Miller, John B, Miller, Scot M, Parazoo, Nicholas C, Randerson, James T, Sweeney, Colm, Tans, Pieter, Thoning, Kirk, Veraverbeke, Sander, Miller, Charles E, and Wofsy, Steven C

Subjects

Climate Action, carbon dioxide, Arctic, early winter respiration, Alaska, tundra

Abstract

High-latitude ecosystems have the capacity to release large amounts of carbon dioxide (CO2) to the atmosphere in response to increasing temperatures, representing a potentially significant positive feedback within the climate system. Here, we combine aircraft and tower observations of atmospheric CO2 with remote sensing data and meteorological products to derive temporally and spatially resolved year-round CO2 fluxes across Alaska during 2012-2014. We find that tundra ecosystems were a net source of CO2 to the atmosphere annually, with especially high rates of respiration during early winter (October through December). Long-term records at Barrow, AK, suggest that CO2 emission rates from North Slope tundra have increased during the October through December period by 73% ± 11% since 1975, and are correlated with rising summer temperatures. Together, these results imply increasing early winter respiration and net annual emission of CO2 in Alaska, in response to climate warming. Our results provide evidence that the decadal-scale increase in the amplitude of the CO2 seasonal cycle may be linked with increasing biogenic emissions in the Arctic, following the growing season. Early winter respiration was not well simulated by the Earth System Models used to forecast future carbon fluxes in recent climate assessments. Therefore, these assessments may underestimate the carbon release from Arctic soils in response to a warming climate.

Published

2017

17. Ecosystem fluxes of hydrogen in a mid‐latitude forest driven by soil microorganisms and plants

Author

Meredith, Laura K, Commane, Róisín, Keenan, Trevor F, Klosterman, Stephen T, Munger, J William, Templer, Pamela H, Tang, Jianwu, Wofsy, Steven C, and Prinn, Ronald G

Subjects

Biological Sciences, Environmental Sciences, Life on Land, Climate Action, Affordable and Clean Energy, Carbon, Carbon Dioxide, Ecosystem, Forests, Hydrogen, Plants, Soil, Soil Microbiology, Trees, atmosphere, carbon cycle, flux, hydrogen, microbe, phenology, snow, soil, Ecology, Biological sciences, Earth sciences, Environmental sciences

Abstract

Molecular hydrogen (H2 ) is an atmospheric trace gas with a large microbe-mediated soil sink, yet cycling of this compound throughout ecosystems is poorly understood. Measurements of the sources and sinks of H2 in various ecosystems are sparse, resulting in large uncertainties in the global H2 budget. Constraining the H2 cycle is critical to understanding its role in atmospheric chemistry and climate. We measured H2 fluxes at high frequency in a temperate mixed deciduous forest for 15 months using a tower-based flux-gradient approach to determine both the soil-atmosphere and the net ecosystem flux of H2 . We found that Harvard Forest is a net H2 sink (-1.4 ± 1.1 kg H2  ha-1 ) with soils as the dominant H2 sink (-2.0 ± 1.0 kg H2  ha-1 ) and aboveground canopy emissions as the dominant H2 source (+0.6 ± 0.8 kg H2  ha-1 ). Aboveground emissions of H2 were an unexpected and substantial component of the ecosystem H2 flux, reducing net ecosystem uptake by 30% of that calculated from soil uptake alone. Soil uptake was highly seasonal (July maximum, February minimum), positively correlated with soil temperature and negatively correlated with environmental variables relevant to diffusion into soils (i.e., soil moisture, snow depth, snow density). Soil microbial H2 uptake was correlated with rhizosphere respiration rates (r = 0.8, P

Published

2017

18. Global Atmospheric Chemistry – Which Air Matters

Author

Prather, Michael J, Zhu, Xin, Flynn, Clare M, Strode, Sarah A, Rodriguez, Jose M, Steenrod, Stephen D, Liu, Junhua, Lamarque, Jean-Francois, Fiore, Arlene M, Horowitz, Larry W, Mao, Jingqiu, Murray, Lee T, Shindell, Drew T, and Wofsy, Steven C

Abstract

Abstract. An approach for analysis and modeling of global atmospheric chemistry is developed for application to measurements that provide a tropospheric climatology of those heterogeneously distributed, reactive species that control the loss of methane and the production and loss of ozone. We identify key species (e.g., O3, NOx, HNO3, HNO4, C2H3NO5, H2O, HOOH, CH3OOH, HCHO, CO, CH4, C2H6, acetaldehyde, acetone), and presume that they can be measured simultaneously in air parcels on the scale of a few km horizontally and a few tenths vertically. Six global models have prepared such climatologies (at model resolution) for August with emphasis on the vast central Pacific and Atlantic Ocean basins. We show clear differences in model generated reactivities as well as species covariances that could readily be discriminated with an unbiased climatology. A primary tool is comparison of multi-dimensional probability densities of key species weighted by frequency of occurrence as well as by the reactivity of the parcels with respect to methane and ozone. The reactivity-weighted probabilities tell us which parcels matter in this case. Testing 100-km scale models with 2-km measurements using these tools also addresses a core question about model resolution and whether fine-scale atmospheric structures matter to the overall ozone and methane budget. A new method enabling these six global chemistry-climate models to ingest an externally-sourced climatology and then compute air parcel reactivity is demonstrated. Such an observed climatology is anticipated from the NASA Atmospheric Tomography (ATom) aircraft mission (2015–2020), measuring the key species, executing profiles over the Pacific and Atlantic Ocean basins. This work is a core part of the design of ATom.

Published

2017

19. Detecting regional patterns of changing CO2 flux in Alaska

Author

Parazoo, Nicholas C, Commane, Roisin, Wofsy, Steven C, Koven, Charles D, Sweeney, Colm, Lawrence, David M, Lindaas, Jakob, Chang, Rachel Y-W, and Miller, Charles E

Subjects

Earth Sciences, Atmospheric Sciences, Biological Sciences, Climate Action, carbon cycle, permafrost thaw, climate, Earth system models, remote sensing

Abstract

With rapid changes in climate and the seasonal amplitude of carbon dioxide (CO2) in the Arctic, it is critical that we detect and quantify the underlying processes controlling the changing amplitude of CO2 to better predict carbon cycle feedbacks in the Arctic climate system. We use satellite and airborne observations of atmospheric CO2 with climatically forced CO2 flux simulations to assess the detectability of Alaskan carbon cycle signals as future warming evolves. We find that current satellite remote sensing technologies can detect changing uptake accurately during the growing season but lack sufficient cold season coverage and near-surface sensitivity to constrain annual carbon balance changes at regional scale. Airborne strategies that target regular vertical profile measurements within continental interiors are more sensitive to regional flux deeper into the cold season but currently lack sufficient spatial coverage throughout the entire cold season. Thus, the current CO2 observing network is unlikely to detect potentially large CO2 sources associated with deep permafrost thaw and cold season respiration expected over the next 50 y. Although continuity of current observations is vital, strategies and technologies focused on cold season measurements (active remote sensing, aircraft, and tall towers) and systematic sampling of vertical profiles across continental interiors over the full annual cycle are required to detect the onset of carbon release from thawing permafrost.

Published

2016

20. A multi-scale comparison of modeled and observed seasonal methane emissions in northern wetlands

Author

Xu, Xiyan, Riley, William J, Koven, Charles D, Billesbach, Dave P, Chang, Rachel Y-W, Commane, Róisín, Euskirchen, Eugénie S, Hartery, Sean, Harazono, Yoshinobu, Iwata, Hiroki, McDonald, Kyle C, Miller, Charles E, Oechel, Walter C, Poulter, Benjamin, Raz-Yaseef, Naama, Sweeney, Colm, Torn, Margaret, Wofsy, Steven C, Zhang, Zhen, and Zona, Donatella

Subjects

Earth Sciences, Atmospheric Sciences, Climate Action, Environmental Sciences, Biological Sciences, Meteorology & Atmospheric Sciences, Ecology, Physical geography and environmental geoscience, Environmental management

Abstract

Wetlands are the largest global natural methane (CH4/ source, and emissions between 50 and 70° N latitude contribute 10-30% to this source. Predictive capability of land models for northern wetland CH4 emissions is still low due to limited site measurements, strong spatial and temporal variability in emissions, and complex hydrological and biogeochemical dynamics. To explore this issue, we compare wetland CH4 emission predictions from the Community Land Model 4.5 (CLM4.5-BGC) with siteto regional-scale observations. A comparison of the CH4 fluxes with eddy flux data highlighted needed changes to the model's estimate of aerenchyma area, which we implemented and tested. The model modification substantially reduced biases in CH4 emissions when compared with CarbonTracker CH4 predictions. CLM4.5 CH4 emission predictions agree well with growing season (May-September) CarbonTracker Alaskan regional-level CH4 predictions and sitelevel observations. However, CLM4.5 underestimated CH4 emissions in the cold season (October-April). The monthly atmospheric CH4 mole fraction enhancements due to wetland emissions are also assessed using the Weather Research and Forecasting-Stochastic Time-Inverted Lagrangian Transport (WRF-STILT) model coupled with daily emissions from CLM4.5 and compared with aircraft CH4 mole fraction measurements from the Carbon in Arctic Reservoirs Vulnerability Experiment (CARVE) campaign. Both the tower and aircraft analyses confirm the underestimate of cold-season CH4 emissions by CLM4.5. The greatest uncertainties in predicting the seasonal CH4 cycle are from the wetland extent, coldseason CH4 production and CH4 transport processes. We recommend more cold-season experimental studies in highlatitude systems, which could improve the understanding and parameterization of ecosystem structure and function during this period. Predicted CH4 emissions remain uncertain, but we show here that benchmarking against observations across spatial scales can inform model structural and parameter improvements.

Published

2016

21. Global emissions of refrigerants HCFC-22 and HFC-134a: Unforeseen seasonal contributions

Author

Xiang, Bin, Patra, Prabir K, Montzka, Stephen A, Miller, Scot M, Elkins, James W, Moore, Fred L, Atlas, Elliot L, Miller, Ben R, Weiss, Ray F, Prinn, Ronald G, and Wofsy, Steven C

Subjects

Climate Action, HCFC-22, HFC-134a, refrigerants, global emissions, emission seasonality

Abstract

HCFC-22 (CHClF2) and HFC-134a (CH2FCF3) are two major gases currently used worldwide in domestic and commercial refrigeration and air conditioning. HCFC-22 contributes to stratospheric ozone depletion, and both species are potent greenhouse gases. In this work, we study in situ observations of HCFC-22 and HFC-134a taken from research aircraft over the Pacific Ocean in a 3-y span [HIaper-Pole-to-Pole Observations (HIPPO) 2009-2011] and combine these data with long-term ground observations from global surface sites [National Oceanic and Atmospheric Administration (NOAA) and Advanced Global Atmospheric Gases Experiment (AGAGE) networks]. We find the global annual emissions of HCFC-22 and HFC-134a have increased substantially over the past two decades. Emissions of HFC-134a are consistently higher compared with the United Nations Framework Convention on Climate Change (UNFCCC) inventory since 2000, by 60% more in recent years (2009-2012). Apart from these decadal emission constraints, we also quantify recent seasonal emission patterns showing that summertime emissions of HCFC-22 and HFC-134a are two to three times higher than wintertime emissions. This unforeseen large seasonal variation indicates that unaccounted mechanisms controlling refrigerant gas emissions are missing in the existing inventory estimates. Possible mechanisms enhancing refrigerant losses in summer are (i) higher vapor pressure in the sealed compartment of the system at summer high temperatures and (ii) more frequent use and service of refrigerators and air conditioners in summer months. Our results suggest that engineering (e.g., better temperature/vibration-resistant system sealing and new system design of more compact/efficient components) and regulatory (e.g., reinforcing system service regulations) steps to improve containment of these gases from working devices could effectively reduce their release to the atmosphere.

Published

2014

22. What drives the seasonality of photosynthesis across the Amazon basin? A cross-site analysis of eddy flux tower measurements from the Brasil flux network

Author

Restrepo-Coupe, Natalia, da Rocha, Humberto R, Hutyra, Lucy R, da Araujo, Alessandro C, Borma, Laura S, Christoffersen, Bradley, Cabral, Osvaldo MR, de Camargo, Plinio B, Cardoso, Fernando L, da Costa, Antonio C Lola, Fitzjarrald, David R, Goulden, Michael L, Kruijt, Bart, Maia, Jair MF, Malhi, Yadvinder S, Manzi, Antonio O, Miller, Scott D, Nobre, Antonio D, von Randow, Celso, Sá, Leonardo D Abreu, Sakai, Ricardo K, Tota, Julio, Wofsy, Steven C, Zanchi, Fabricio B, and Saleska, Scott R

Subjects

Life on Land, Tropical forest, Eddy covariance, Amazon, Seasonality, Ecosystem productivity, Cross-site, Earth Sciences, Biological Sciences, Agricultural and Veterinary Sciences, Meteorology & Atmospheric Sciences

Abstract

We investigated the seasonal patterns of Amazonian forest photosynthetic activity, and the effects thereon of variations in climate and land-use, by integrating data from a network of ground-based eddy flux towers in Brazil established as part of the 'Large-Scale Biosphere Atmosphere Experiment in Amazonia' project. We found that degree of water limitation, as indicated by the seasonality of the ratio of sensible to latent heat flux (Bowen ratio) predicts seasonal patterns of photosynthesis. In equatorial Amazonian forests (5° N-5° S), water limitation is absent, and photosynthetic fluxes (or gross ecosystem productivity, GEP) exhibit high or increasing levels of photosynthetic activity as the dry season progresses, likely a consequence of allocation to growth of new leaves. In contrast, forests along the southern flank of the Amazon, pastures converted from forest, and mixed forest-grass savanna, exhibit dry-season declines in GEP, consistent with increasing degrees of water limitation. Although previous work showed tropical ecosystem evapotranspiration (ET) is driven by incoming radiation, GEP observations reported here surprisingly show no or negative relationships with photosynthetically active radiation (PAR). Instead, GEP fluxes largely followed the phenology of canopy photosynthetic capacity (Pc), with only deviations from this primary pattern driven by variations in PAR. Estimates of leaf flush at three non-water limited equatorial forest sites peak in the dry season, in correlation with high dry season light levels. The higher photosynthetic capacity that follows persists into the wet season, driving high GEP that is out of phase with sunlight, explaining the negative observed relationship with sunlight. Overall, these patterns suggest that at sites where water is not limiting, light interacts with adaptive mechanisms to determine photosynthetic capacity indirectly through leaf flush and litterfall seasonality. These mechanisms are poorly represented in ecosystem models, and represent an important challenge to efforts to predict tropical forest responses to climatic variations. © 2013 Elsevier B.V.

Published

2013

23. Atmospheric Carbon Dioxide Variability in the Community Earth System Model: Evaluation and Transient Dynamics during the Twentieth and Twenty-First Centuries

Author

Keppel-Aleks, Gretchen, Randerson, James T, Lindsay, Keith, Stephens, Britton B, Keith Moore, J., Doney, Scott C, Thornton, Peter E, Mahowald, Natalie M, Hoffman, Forrest M, Sweeney, Colm, Tans, Pieter P, Wennberg, Paul O, and Wofsy, Steven C

Subjects

Atmospheric carbon dioxide, Atmospheric observations, Community land models, Fossil fuel emissions, Horizontal gradients, Interannual variability, Northern Hemispheres, Three-dimensional structure, Atmospheric chemistry, Climate change, Fossil fuels, Carbon dioxide, annual variation, biogeochemistry, carbon dioxide, climate change, computer simulation, ecosystem response, environmental monitoring, Northern Hemisphere, spatiotemporal analysis, twentieth century, twenty first century

Abstract

Changes in atmospheric CO2 variability during the twenty-first century may provide insight about ecosystem responses to climate change and have implications for the design of carbon monitoring programs. This paper describes changes in the three-dimensional structure of atmospheric CO2 for several representative concentration pathways (RCPs 4.5 and 8.5) using the Community Earth System Model–Biogeochemistry (CESM1-BGC). CO2 simulated for the historical period was first compared to surface, aircraft, and column observations. In a second step, the evolution of spatial and temporal gradients during the twenty-first century was examined. The mean annual cycle in atmospheric CO2 was underestimated for the historical period throughout the Northern Hemisphere, suggesting that the growing season net flux in the Community Land Model (the land component of CESM) was too weak. Consistent with weak summer drawdown in Northern Hemisphere high latitudes, simulated CO2 showed correspondingly weak north–south and vertical gradients during the summer. In the simulations of the twenty-first century, CESM predicted increases in the mean annual cycle of atmospheric CO2 and larger horizontal gradients. Not only did the mean north–south gradient increase due to fossil fuel emissions, but east–west contrasts in CO2 also strengthened because of changing patterns in fossil fuel emissions and terrestrial carbon exchange. In the RCP8.5 simulation, where CO2 increased to 1150 ppm by 2100, the CESM predicted increases in interannual variability in the Northern Hemisphere midlatitudes of up to 60% relative to present variability for time series filtered with a 2–10-yr bandpass. Such an increase in variability may impact detection of changing surface fluxes from atmospheric observations.

Published

2013

24. Correction: Corrigendum: The Amazon basin in transition

Author

Davidson, Eric A, de Araújo, Alessandro C, Artaxo, Paulo, Balch, Jennifer K, Brown, I Foster, Bustamante, Mercedes MC, Coe, Michael T, DeFries, Ruth S, Keller, Michael, Longo, Marcos, Munger, J William, Schroeder, Wilfrid, Soares-Filho, Britaldo S, Souza, Carlos M, and Wofsy, Steven C

Subjects

General Science & Technology

Published

2012

25. Patterns of water and heat flux across a biome gradient from tropical forest to savanna in Brazil

Author

da Rocha, Humberto R., Manzi, Antonio O., Cabral, Osvaldo M., Miller, Scott D., Goulden, Michael L., Saleska, Scott R., R.-Coupe, Natalia, Wofsy, Steven C., Borma, Laura S., Artaxo, P., Vourlitis, George, Nogueira, José S., Cardoso, Fernando L., Nobre, Antonio D., Kruijt, Bart, Freitas, Helber C., von Randow, Celso, Aguiar, Renata G., and Maia, Jair F.

Subjects

tropical forest, evaporation, cerrado, savanna, Amazonia

Abstract

We investigated the seasonal patterns of water vapor and sensible heat flux along a tropical biome gradient from forest to savanna. We analyzed data from a network of flux towers in Brazil that were operated within the Large-Scale Biosphere-Atmosphere Experiment in Amazonia (LBA). These tower sites included tropical humid and semideciduous forest, transitional forest, floodplain (with physiognomies of cerrado), and cerrado sensu stricto. The mean annual sensible heat flux at all sites ranged from 20 to 38 Wm−2, and was generally reduced in the wet season and increased in the late dry season, coincident with seasonal variations of net radiation and soil moisture. The sites were easily divisible into two functional groups based on the seasonality of evaporation: tropical forest and savanna. At sites with an annual precipitation above 1900 mm and a dry season length less than 4 months (Manaus, Santarem and Rondonia), evaporation rates increased in the dry season, coincident with increased radiation. Evaporation rates were as high as 4.0 mm d−1 in these evergreen or semidecidous forests. In contrast, ecosystems with precipitation less than 1700 mm and a longer dry season (Mato Grosso, Tocantins and São Paulo) showed clear evidence of reduced evaporation in the dry season. Evaporation rates were as low as 2.5 mm d−1 in the transitional forests and 1 mm d−1 in the cerrado. The controls on evapotranspiration seasonality changed along the biome gradient, with evaporative demand (especially net radiation) playing a more important role in the wetter forests, and soil moisture playing a more important role in the drier savannah sites.

Published

2009

26. Deriving a light use efficiency model from eddy covariance flux data for predicting daily gross primary production across biomes

Author

Yuan, Wenping, Liu, Shuguang, Zhou, Guangsheng, Zhou, Guoyi, Tieszen, Larry L., Baldocchi, Dennis, Bernhofer, Christian, Gholz, Henry, Goldstein, Allen H., Goulden, Michael L., Hollinger, David Y., Hu, Yueming, Law, Beverly E., Stoy, Paul C., Vesala, Timo, and Wofsy, Steven C.

Subjects

gross primary production, light use efficiency, eddy covariance, EC-LUE model, evaporative fraction, NDVI

Abstract

The quantitative simulation of gross primary production (GPP) at various spatial and temporal scales has been a major challenge in quantifying the global carbon cycle. We developed a light use efficiency (LUE) daily GPP model from eddy covariance (EC) measurements. The model, called EC-LUE, is driven by only four variables: normalized difference vegetation index (NDVI), photosynthetically active radiation (PAR), air temperature, and the Bowen ratio of sensible to latent heat flux (used to calculate moisture stress). The EC-LUE model relies on two assumptions: First, that the fraction of absorbed PAR (fPAR) is a linear function of NDVI; Second, that the realized light use efficiency, calculated from a biome-independent invariant potential LUE, is controlled by air temperature or soil moisture, whichever is most limiting. The EC-LUE model was calibrated and validated using 24,349 daily GPP estimates derived from 28 eddy covariance flux towers from the AmeriFlux and EuroFlux networks, covering a variety of forests, grasslands and savannas. The model explained 85% and 77% of the observed variations of daily GPP for all the calibration and validation sites, respectively. A comparison with GPP calculated from the Moderate Resolution Imaging Spectroradiometer (MODIS) indicated that the EC-LUE model predicted GPP that better matched tower data across these sites. The realized LUE was predominantly controlled by moisture conditions throughout the growing season, and controlled by temperature only at the beginning and end of the growing season. The EC-LUE model is an alternative approach that makes it possible to map daily GPP over large areas because (1) the potential LUE is invariant across various land cover types and (2) all driving forces of the model can be derived from remote sensing data or existing climate observation networks.

Published

2007

27. A long‐term record of carbon exchange in a boreal black spruce forest: means, responses to interannual variability, and decadal trends

Author

DUNN, ALLISON L, BARFORD, CAROL C, WOFSY, STEVEN C, GOULDEN, MICHAEL L, and DAUBE, BRUCE C

Subjects

Climate Action, boreal, black spruce, decomposition, global change, interannual variability, net ecosystem exchange, peatland, photosynthesis, Picea mariana, soil carbon, Environmental Sciences, Biological Sciences, Ecology

Abstract

We present a decadal (1994-2004) record of carbon dioxide flux in a 160-year-old black spruce forest/veneer bog complex in central Manitoba, Canada. The ecosystem shifted from a source (+41 g Cm-2, 1995) to a sink (-21 g C m-2, 2004) of CO2 over the decade, with an average net carbon balance near zero. Annual mean temperatures increased 1-2° during the period, consistent with the decadal trend across the North American boreal biome. We found that ecosystem carbon exchange responded strongly to air temperature, moisture status, potential evapotranspiration, and summertime solar radiation. The seasonal cycle of ecosystem respiration significantly lagged that of photosynthesis, limited by the rate of soil thaw and the slow drainage of the soil column. Factors acting over long time scales, especially water table depth, strongly influenced the carbon budget on annual time scales. Net uptake was enhanced and respiration inhibited by multiple years of rainfall in excess of evaporative demand. Contrary to expectations, we observed no correlation between longer growing seasons and net uptake, possibly because of offsetting increases in ecosystem respiration. The results indicate that the interactions between soil thaw and water table depth provide critical controls on carbon exchange in boreal forests underlain by peat, on seasonal to decadal time scales, and these factors must be simulated in terrestrial biosphere models to predict response of these regions to future climate. © 2007 Blackwell Publishing Ltd.

Published

2007

28. Forest structure and carbon dynamics in Amazonian tropical rain forests

Author

Vieira, Simone, de Camargo, Plinio Barbosa, Selhorst, Diogo, da Silva, Roseana, Hutyra, Lucy, Chambers, Jeffrey Q, Brown, I Foster, Higuchi, Niro, dos Santos, Joaquim, Wofsy, Steven C, Trumbore, Susan E, and Martinelli, Luiz Antonio

Subjects

Biomass, Brazil, Carbon, Ecosystem, Environmental Monitoring, Rain, Seasons, Trees, Tropical Climate, carbon, forest dynamics, tropical forest, growth rate, dendrometry, Ecology

Abstract

Living trees constitute one of the major stocks of carbon in tropical forests. A better understanding of variations in the dynamics and structure of tropical forests is necessary for predicting the potential for these ecosystems to lose or store carbon, and for understanding how they recover from disturbance. Amazonian tropical forests occur over a vast area that encompasses differences in topography, climate, and geologic substrate. We observed large differences in forest structure, biomass, and tree growth rates in permanent plots situated in the eastern (near Santarém, Pará), central (near Manaus, Amazonas) and southwestern (near Rio Branco, Acre) Amazon, which differed in dry season length, as well as other factors. Forests at the two sites experiencing longer dry seasons, near Rio Branco and Santarém, had lower stem frequencies (460 and 466 ha(-1) respectively), less biodiversity (Shannon-Wiener diversity index), and smaller aboveground C stocks (140.6 and 122.1 Mg C ha(-1)) than the Manaus site (626 trees ha(-1), 180.1 Mg C ha(-1)), which had less seasonal variation in rainfall. The forests experiencing longer dry seasons also stored a greater proportion of the total biomass in trees with >50 cm diameter (41-45 vs 30% in Manaus). Rates of annual addition of C to living trees calculated from monthly dendrometer band measurements were 1.9 (Manaus), 2.8 (Santarém), and 2.6 (Rio Branco) Mg C ha(-1) year(-1). At all sites, trees in the 10-30 cm diameter class accounted for the highest proportion of annual growth (38, 55 and 56% in Manaus, Rio Branco and Santarém, respectively). Growth showed marked seasonality, with largest stem diameter increment in the wet season and smallest in the dry season, though this may be confounded by seasonal variation in wood water content. Year-to-year variations in C allocated to stem growth ranged from nearly zero in Rio Branco, to 0.8 Mg C ha(-1) year(-1) in Manaus (40% of annual mean) and 0.9 Mg C ha(-1) year(-1) (33% of annual mean) in Santarém, though this variability showed no significant relation with precipitation among years. Initial estimates of the C balance of live wood including recruitment and mortality as well as growth suggests that live wood biomass is at near steady-state in Manaus, but accumulating at about 1.5 Mg C ha(-1) at the other two sites. The causes of C imbalance in living wood pools in Santarém and Rio Branco sites are unknown, but may be related to previous disturbance at these sites. Based on size distribution and growth rate differences in the three sites, we predict that trees in the Manaus forest have greater mean age (approximately 240 years) than those of the other two forests (approximately 140 years).

Published

2004

29. Carbon in Amazon Forests: Unexpected Seasonal Fluxes and Disturbance-Induced Losses

Author

Saleska, S. R., Miller, Scott D., Matross, Daniel M., Goulden, Michael L., Wofsy, Steven C., da Rocha, Humberto R., de Camargo, Plinio B., Crill, Patrick, Daube, Bruce C., de Freitas, Helber C., Hutyra, Lucy, Keller, Michael, Kirchhoff, Volker, Menton, Mary, Munger, J. William, Pyle, Elizabeth Hammond, Rice, Amy H., and Silva, Hudson

Abstract

The net ecosystem exchange of carbon dioxide was measured by eddy covariance methods for 3 years in two old-growth forest sites near Santarém, Brazil. Carbon was lost in the wet season and gained in the dry season, which was opposite to the seasonal cycles of both tree growth and model predictions. The 3-year average carbon loss was 1.3 (confidence interval: 0.0 to 2.0) megagrams of carbon per hectare per year. Biometric observations confirmed the net loss but imply that it is a transient effect of recent disturbance superimposed on long-term balance. Given that episodic disturbances are characteristic of old-growth forests, it is likely that carbon sequestration is lower than has been inferred from recent eddy covariance studies at undisturbed sites.

Published

2003

30. Seasonal course of isoprene emissions from a midlatitude deciduous forest

Author

Goldstein, Allen H., Goulden, Michael L., Munger, J. William, Wofsy, Steven C., and Geron, Christopher D.

Subjects

pollution, Biosphere/atmosphere interactions, constituent sources and sinks, Troposphere

Abstract

Continuous measurements of whole canopy isoprene emissions over an entire growing season are reported from Harvard Forest (42°32′N, 72°11′W). Emissions were calculated from the ratio of observed CO2 flux and gradient multiplied by the observed hydrocarbon gradients. In summer 1995, 24-hour average emissions of isoprene from June 1 through October 31 were 32.7×1010 molecules cm−2 s−l (mg C m−2 h−l = 2.8 × 1011 molecules cm−2 s−1), and the mean midday mixing ratio was 4.4 ppbv at 24 m. Isoprene emissions were zero at night, increased through the morning with increasing air temperature and light, reached a peak in the afternoon between the peaks in air temperature and light, and then declined with light. Isoprene emissions were observed over a shorter seasonal period than photosynthetic carbon uptake. Isoprene emission was not detected from young leaves and reached a peak rate (normalized for response to measured light and temperature conditions) 4 weeks after leaf out and 2 weeks after emissions began. The normalized emission rate remained constant for approximately 65 days, then decreased steadily through September and into October. Total isoprene emissions over the growing season (42 kg C ha−1 yr−1) were equal to 2% of the annual net uptake of carbon by the forest. Measured isoprene emissions were higher than the Biogenic Emission Inventory System-II model by at least 40% at midday and showed distinctly different diurnal and seasonal emission patterns. Seasonal adjustment factors (in addition to the light and temperature factors) should be incorporated into future empirical models of isoprene emissions. Comparison of measured isoprene emissions with estimates of anthropogenic volatile organic compound emissions suggests that isoprene is more important for ozone production in much of Massachusetts on hot summer days when the highest ozone events occur.

Published

1998

31. Regional budgets for nitrogen oxides from continental sources: Variations of rates for oxidation and deposition with season and distance from source regions

Author

Munger, J. William, Fan, Song-Miao, Bakwin, Peter S., Goulden, Mike L., Goldstein, Allen. H., Colman, Albert S., and Wofsy, Steven C.

Subjects

constituent sources and sinks, Troposphere, pollution, chemistry

Abstract

Measurements of nitrogen deposition and concentrations of NO, NO2, NO y (total oxidized N), and O3 have been made at Harvard Forest in central Massachusetts since 1990 to define the atmospheric budget for reactive N near a major source region. Total (wet plus dry) reactive N deposition for the period 1990–1996 averaged 47 mmol m−2 yr−1 (126 μmol m−2 d−1, 6.4 kg N ha−1 yr−1), with 34% contributed by dry deposition. Atmospheric input adds about 12% to the N made available annually by mineralization in the forest soil. The corresponding deposition rate at a distant site, Schefferville, Quebec, was 20 mmol m−2 d−1 during summer 1990. Both heterogeneous and homogeneous reactions efficiently convert NO x to HNO3 in the boundary layer. HNO3 is subsequently removed rapidly by either dry deposition or precipitation. The characteristic (e-folding) time for NO x oxidation ranges from 0.30 days in summer, when OH radical is abundant, to ∼1.5 days in the winter, when heterogeneous reactions are dominant and O3 concentrations are lowest. The characteristic time for removal of NO x oxidation products (defined as NO y minus NO x) from the boundary layer by wet and dry deposition is ∼1 day, except in winter when it decreases to 0.6 day. Biogenic hydrocarbons contribute to N deposition through formation of organic nitrates but are also precursors of reservoir species, such as peroxyacetylnitrate, that may be exported from the region. A simple model assuming pseudo first-order rates for oxidation of NO x, followed by deposition, predicts that 45% of NO x in the northeastern U.S. boundary layer is removed in 1 day during summer and 27% is removed in winter. It takes 3.5 and 5 days for 95% removal in summer and winter, respectively.

Published

1998

32. Physiological responses of a black spruce forest to weather

Author

Goulden, Michael L., Daube, Bruce C., Fan, Song-Miao, Sutton, Douglas J., Bazzaz, Ammar, Munger, J. William, and Wofsy, Steven C.

Subjects

plant ecology, Biosphere/atmosphere interactions, evapotranspiration

Abstract

We used eddy covariance to measure the net exchange of CO2 between the atmosphere and a black spruce (Picea mariana) forest in Manitoba for 16,500 hours from March 16, 1994 to October 31, 1996. We then partitioned net exchange into gross photosynthesis and respiration by estimating daytime respiration as a function of temperature, and used these data to define the physiological responses of the forest to weather. The annual rates of gross production and respiration by the forest were both around 8 t C ha−1 yr−1. Both photosynthetic and respiratory response were reduced in winter, recovered with warming in spring, and varied little in summer. Respiration in mid summer increased with air temperature (T air) at a Q 10 of around 2 to a rate of 2–8 μmol m−2 s−1 at 15°C. Gross photosynthesis at high light (photon flux density (PPFD) greater than 600 μmol m−2 s−1) was negligible at Tair < 0°C, increased linearly with Tair from 0° to 14°C, and was relatively insensitive to T air > 14°C. Gross CO2 uptake at T air > 14°C increased with increasing light at an ecosystem-level quantum yield of 0.05 mol CO2 mol−1 photons before saturating at an uptake rate of 8–18 μmol m−2 s−1 at PPFDs greater than 500–700 μmol m−2 s−1. Photosynthesis in summer did not appear limited by high evaporative demand or soil water depletion.

Published

1997

33. Atmospheric deposition of reactive nitrogen oxides and ozone in a temperate deciduous forest and a subarctic woodland: 1. Measurements and mechanisms

Author

Munger, J William, Wofsy, Steven C, Bakwin, Peter S, Fan, Song‐Miao, Goulden, Michael L, Daube, Bruce C, Goldstein, Allen H, Moore, Kathleen E, and Fitzjarrald, David R

Subjects

Meteorology & Atmospheric Sciences

Published

1996

34. Seasonal Variation in Radiative and Turbulent Exchange at a Deciduous Forest in Central Massachusetts

Author

Moore, Kathleen E., Fitzjarrald, David R., Sakai, Ricardo K., Goulden, Michael L., Munger, J. William, and Wofsy, Steven C.

Published

1996

35. Factors influencing atmospheric composition over subarctic North America during summer

Author

Wofsy, Steven C, Fan, S‐M, Blake, DR, Bradshaw, JD, Sandholm, ST, Singh, HB, Sachse, GW, and Harriss, RC

Subjects

Meteorology & Atmospheric Sciences

Published

1994

36. Reactive nitrogen oxides and ozone above a taiga woodland

Author

Bakwin, Peter S, Jacob, Daniel J, Wofsy, Steven C, Munger, J William, Daube, Bruce C, Bradshaw, John D, Sandholm, Scott T, Talbot, Robert W, Singh, Hanwant B, Gregory, Gerald L, and Blake, Donald R

Subjects

Meteorology & Atmospheric Sciences

Published

1994

37. Simulation of summertime ozone over North America

Author

Jacob, Daniel J, Logan, Jennifer A, Yevich, Rose M, Gardner, Geraldine M, Spivakovsky, Clarisa M, Wofsy, Steven C, Munger, J. William, Sillman, Sanford, Prather, Michael J, Rodgers, Michael O, Westberg, Hal, and Zimmerman, Patrick R

Subjects

Eastern-United-States, tropospheric OH, reactive nitrogen, acid deposition, carbon-monoxide, sulfur-dioxide, oxidant model, chemistry, site, surface

Abstract

The concentrations of O3 and its precursors over North America are simulated for three summer months with a three-dimensional, continental-scale photochemical model using meteorological input from the Goddard Institute for Space Studies (GISS) general circulation model (GCM). The model has 4°×5° grid resolution and represents non linear chemistry in urban and industrial plumes with a subgrid nested scheme. Simulated median afternoon O3 concentrations at rural U.S. sites are within 5 ppb of observations in most cases, except in the south central United States where concentrations are overpredicted by 15–20 ppb. The model captures successfully the development of regional high-O3 episodes over the northeastern United States on the back side of weak, warm, stagnant anticyclones. Simulated concentrations of CO and nonmethane hydrocarbons are generally in good agreement with observations, concentrations of NOx are underpredicted by 10–30%, and concentrations of peroxyacylnitrates (PANs) are overpredicted by a factor of 2 to 3. The overprediction of PANs is attributed to flaws in the photochemical mechanism, including excessive production from oxidation of isoprene, and may also reflect an underestimate of PANs deposition. Subgrid nonlinear chemistry as captured by the nested plumes scheme decreases the net O3 production computed in the United States boundary layer by 8% on average.

Published

1993

38. Factors regulating ozone over the United States and its export to the global atmosphere

Author

Jacob, Daniel J, Logan, Jennifer A, Gardner, Geraldine M, Yevich, Rose M, Spivakovsky, Clarisa M, Wofsy, Steven C, Sillman, Sanford, and Prather, Michael J

Subjects

tropospheric ozone, biogenic hydrocarbons, reactive nitrogen, rural ozone, model, emissions, budget, urban, photochemistry, sensitivity

Abstract

The factors regulating summertime O3 over the United States and its export to the global atmosphere are examined with a 3-month simulation using a continental scale, three-dimensional photochemical model. It is found that reducing NOx emissions by 50% from 1985 levels would decrease rural O3 concentrations over the eastern United States by about 15% under almost all meteorological conditions, while reducing anthropogenic hydrocarbon emissions by 50% would have less than a 4% effect except in the largest urban plumes. The strongly NOx-limited conditions in the model reflect the dominance of rural areas as sources of O3 on the regional scale. The correlation between O3 concentrations and temperature observed at eastern U.S. sites is attributed in part to the association of high temperatures with regional stagnation, and in part to an actual dependence of O3 production on temperature driven primarily by conversion of NOx to peroxyacetylnitrate (PAN). The net number of O3 molecules produced per molecule of NOx consumed (net O3 production efficiency, accounting for both chemical production and chemical loss of O3) has a mean value of 6.3 in the U.S. boundary layer; it is 3 times higher in the western United States than in the east because of lower NOx concentrations in the west. Approximately 70% of the net chemical production of O3 in the U.S. boundary layer is exported (the rest is deposited). Only 6% of the NOx emitted in the United States is exported out of the U.S. boundary layer as NOx or PAN, but this export contributes disproportionately to total U.S. influence on global tropospheric O3because of the high O3 production efficiency per unit NOx in the remote troposphere. It is estimated that export of U.S. pollution supplies 8 Gmol O3 d−1 to the global troposphere in summer, including 4 Gmol d−1 from direct export of O3 out of the U.S. boundary layer and 4 Gmol d−1 from production of O3 downwind of the United States due to exported NOx. This U.S. pollution source can be compared to estimates of 18–28 Gmol d−1 for the cross-tropopause transport of O3 over the entire northern hemisphere in summer.

Published

1993

39. Emission of nitric oxide (NO) from tropical forest soils and exchange of NO between the forest canopy and atmospheric boundary layers

Author

Bakwin, Peter S, Wofsy, Steven C, Fan, Song-Miao, Keller, Michael, Trumbore, Susan E, and Da Costa, Jose Maria

Subjects

boundary layer, canopy, clay, dry season, nitric oxide, rain forest, tropical forest soil, wet season, Brazil, Amazon

Abstract

Emissions of NO from soils in the Amazon rain forest were measured at 66 locations (224 measurements) using an enclosure technique, and continuous vertical profiles of NO and O3 were measured between the ground and 41-m altitude. Fluxes of NO averaged 8.9 (±1.5) × 109 molecules cm−2 s−1 from the dominant (yellow clay) soils of the region, with larger fluxes (33.7 (±6.5) × 109 molecules cm−2 s−1) observed from adjacent white sand soils. Fluxes from clay soils were lower by more than a factor of 5 than fluxes observed during the dry season at a nearby site. Low soil emission rates were reflected in lower concentrations of NO at the top of the forest canopy in the wet season, only 30–50 pptv (parts per trillion by volume) during the daytime. The measured fluxes are consistent with chemical mass balances for NO within the forest canopy, calculated from the NO and O3 profiles taken at night, and with observations of NO between 150 and 5000 m altitude (A. L. Torres and K. R. Hooks, unpublished manuscript, 1989). Measurements of NO emission rates from soil plots fertilized using NaNO3, NH4Cl or sucrose indicated that a reductive pathway (denitrification) may have been primarily responsible for production of the NO released by both clay and sand soils.

Published

1990

40. 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

41. Reductions in ozone at high concentrations of stratospheric halogens

Author

Prather, Michael J, McElroy, Michael B, and Wofsy, Steven C

Subjects

Earth Sciences, Atmospheric Sciences, Atmosphere, Bromine, Chlorine, Chlorofluorocarbons, Halogens, Hydroxyl Radical, Methane, Nitrogen, Ozone, Photochemistry, General Science & Technology

Abstract

An increase in the concentration of inorganic chlorine to levels comparable to that of oxidized reactive nitrogen could cause a significant change in the chemistry of the lower stratosphere leading to a reduction potentially larger than 15% in the column density of ozone. This could occur, for example by the middle of the next century, if emissions of man-made chlorocarbons were to grow at a rate of 3% per year. Ozone could be further depressed by release of industrial bromocarbon.

Published

1984

42. Oxidation of CS2 and COS: sources for atmospheric SO2

Author

Logan, Jennifer A, McElroy, Michael B, Wofsy, Steven C, and Prather, Michael J

Subjects

General Science & Technology

Abstract

Oxidation of CS2 and COS initiated by reaction with OH can provide a source of atmospheric SO2 as large as 12 Mtonnes S yr -1 and may represent the dominant source of SO2 in remote regions of the marine troposphere. © 1979 Nature Publishing Group.

Published

1979

43. Tropospheric chemistry: A global perspective

Author

Logan, Jennifer A, Prather, Michael J, Wofsy, Steven C, and McElroy, Michael B

Subjects

ozone, troposphere, atmospheric processes, atmosphere

Abstract

A model for the photochemistry of the global troposphere constrained by observed concentrations of H2O, O3, CO, CH4, NO, NO2, and HNO3 is presented. Data for NO and NO2 are insufficient to define the global distribution of these gases but are nonetheless useful in limiting several of the more uncertain parameters of the model. Concentrations of OH, HO2, H2O2, NO, NO2, NO3, N2O5, HNO2, HO2NO2, CH3O2, CH3OOH, CH2O, and CH3CCl3 are calculated as functions of altitude, latitude, and season. Results imply that the source for nitrogen oxides in the remote troposphere is geographically dispersed and surprisingly small, less than 107 tons N yr−1. Global sources for CO and CH4 are 1.5 × 109 tons C yr−1 and 4.5 × 108 tons C yr−1, respectively. Carbon monoxide is derived from combustion of fossil fuel (15%) and oxidation of atmospheric CH4 (25%), with the balance from burning of vegetation and oxidation of biospheric hydrocarbons. Production of CO in the northern hemisphere exceeds that in the southern hemisphere by about a factor of 2. Industrial and agricultural activities provide approximately half the global source of CO. Oxidation of CO and CH4 provides sources of tropospheric O3 similar in magnitude to loss by in situ photochemistry. Observations of CH3CCl3 could offer an important check of the tropospheric model and results shown here suggest that computed concentrations of OH should be reliable within a factor of 2. A more definitive test requires better definition of release rates for CH3CCl3 and improved measurements for its distribution in the atmosphere.

Published

1981

44. Atmospheric distribution of 85 Kr simulated with a general circulation model

Author

Jacob, Daniel J, Prather, Michael J, Wofsy, Steven C, and McElroy, Michael B

Subjects

krypton, atmosphere, geochemical cycles, meteorology and atmospheric dynamics, general circulation

Abstract

A three-dimensional chemical tracer model for the troposphere is used to simulate the global distribution of 85Kr, a long-lived radioisotope released at northern mid-latitudes by nuclear industry. Simulated distributions for the period 1980–1983 are in excellent agreement with data from six latitudinal profiles measured over the Atlantic. High concentrations of 85Kr are predicted over the Arctic in winter, advected from European sources, and somewhat smaller enhancements arising from the same sources are predicted over the tropical Atlantic in summer. Latitudinal gradients are steepest in the northern tropics, with distinctly different seasonal variations over the Pacific, as compared to the Atlantic. The global inventory of 85Kr is reconstructed for the period 1980–1983 by combining the concentrations measured over the Atlantic with the global distributions predicted by the model. The magnitude of the Soviet source is derived. The interhemispheric exchange time is calculated as 1.1 years, with little seasonal dependence.

Published

1987