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146 results on '"Lombardozzi, Danica L."'

3. Diagnosing destabilization risk in global land carbon sinks

Author

Fernández-Martínez, Marcos, Peñuelas, Josep, Chevallier, Frederic, Ciais, Philippe, Obersteiner, Michael, Rödenbeck, Christian, Sardans, Jordi, Vicca, Sara, Yang, Hui, Sitch, Stephen, Friedlingstein, Pierre, Arora, Vivek K., Goll, Daniel S., Jain, Atul K., Lombardozzi, Danica L., McGuire, Patrick C., and Janssens, Ivan A.

Published
2023
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4. Dry Deposition of Ozone Over Land: Processes, Measurement, and Modeling

Author

Clifton, Olivia E, Fiore, Arlene M, Massman, William J, Baublitz, Colleen B, Coyle, Mhairi, Emberson, Lisa, Fares, Silvano, Farmer, Delphine K, Gentine, Pierre, Gerosa, Giacomo, Guenther, Alex B, Helmig, Detlev, Lombardozzi, Danica L, Munger, J William, Patton, Edward G, Pusede, Sally E, Schwede, Donna B, Silva, Sam J, Sörgel, Matthias, Steiner, Allison L, and Tai, Amos PK

Subjects
Climate-Related Exposures and Conditions, Climate Action, dry deposition, tropospheric ozone, air pollution, stomatal conductance, eddy covariance, land-atmosphere interactions, Biosphere/atmosphere interactions, Constituent sources and sinks, Pollution: urban and regional, Troposphere: composition and chemistry, Biogeochemical cycles, processes and modeling, Dry deposition, Physical Sciences, Earth Sciences, Engineering, Meteorology & Atmospheric Sciences
Abstract

Dry deposition of ozone is an important sink of ozone in near surface air. When dry deposition occurs through plant stomata, ozone can injure the plant, altering water and carbon cycling and reducing crop yields. Quantifying both stomatal and nonstomatal uptake accurately is relevant for understanding ozone's impact on human health as an air pollutant and on climate as a potent short-lived greenhouse gas and primary control on the removal of several reactive greenhouse gases and air pollutants. Robust ozone dry deposition estimates require knowledge of the relative importance of individual deposition pathways, but spatiotemporal variability in nonstomatal deposition is poorly understood. Here we integrate understanding of ozone deposition processes by synthesizing research from fields such as atmospheric chemistry, ecology, and meteorology. We critically review methods for measurements and modeling, highlighting the empiricism that underpins modeling and thus the interpretation of observations. Our unprecedented synthesis of knowledge on deposition pathways, particularly soil and leaf cuticles, reveals process understanding not yet included in widely-used models. If coordinated with short-term field intensives, laboratory studies, and mechanistic modeling, measurements from a few long-term sites would bridge the molecular to ecosystem scales necessary to establish the relative importance of individual deposition pathways and the extent to which they vary in space and time. Our recommended approaches seek to close knowledge gaps that currently limit quantifying the impact of ozone dry deposition on air quality, ecosystems, and climate.

Published
2020

5. Beyond Static Benchmarking: Using Experimental Manipulations to Evaluate Land Model Assumptions.

Author

Wieder, William R, Lawrence, David M, Fisher, Rosie A, Bonan, Gordon B, Cheng, Susan J, Goodale, Christine L, Grandy, A Stuart, Koven, Charles D, Lombardozzi, Danica L, Oleson, Keith W, and Thomas, R Quinn

Subjects
Community Land Model, biogeochemistry, elevated CO2, land model, nitrogen enrichment, Atmospheric Sciences, Geochemistry, Oceanography, Meteorology & Atmospheric Sciences
Abstract

Land models are often used to simulate terrestrial responses to future environmental changes, but these models are not commonly evaluated with data from experimental manipulations. Results from experimental manipulations can identify and evaluate model assumptions that are consistent with appropriate ecosystem responses to future environmental change. We conducted simulations using three coupled carbon-nitrogen versions of the Community Land Model (CLM, versions 4, 4.5, and-the newly developed-5), and compared the simulated response to nitrogen (N) and atmospheric carbon dioxide (CO2) enrichment with meta-analyses of observations from similar experimental manipulations. In control simulations, successive versions of CLM showed a poleward increase in gross primary productivity and an overall bias reduction, compared to FLUXNET-MTE observations. Simulations with N and CO2 enrichment demonstrate that CLM transitioned from a model that exhibited strong nitrogen limitation of the terrestrial carbon cycle (CLM4) to a model that showed greater responsiveness to elevated concentrations of CO2 in the atmosphere (CLM5). Overall, CLM5 simulations showed better agreement with observed ecosystem responses to experimental N and CO2 enrichment than previous versions of the model. These simulations also exposed shortcomings in structural assumptions and parameterizations. Specifically, no version of CLM captures changes in plant physiology, allocation, and nutrient uptake that are likely important aspects of terrestrial ecosystems' responses to environmental change. These highlight priority areas that should be addressed in future model developments. Moving forward, incorporating results from experimental manipulations into model benchmarking tools that are used to evaluate model performance will help increase confidence in terrestrial carbon cycle projections.

Published
2019

7. Monoterpene ‘thermometer’ of tropical forest‐atmosphere response to climate warming

Author

Jardine, Kolby J, Jardine, Angela B, Holm, Jennifer A, Lombardozzi, Danica L, Negron‐Juarez, Robinson I, Martin, Scot T, Beller, Harry R, Gimenez, Bruno O, Higuchi, Niro, and Chambers, Jeffrey Q

Subjects
Plant Biology, Biological Sciences, Climate Action, Atmosphere, Carbon, Carbon Dioxide, Carbon Isotopes, Circadian Rhythm, Climate Change, El Nino-Southern Oscillation, Forests, Monoterpenes, Plant Leaves, Seasons, Temperature, Tropical Climate, Volatile Organic Compounds, (CO2)-C-13 labeling, drought, El Nino, heat, photosynthesis: carbon reactions, secondary organic aerosols, TPS synthase, volatile emissions, 13CO2 labeling, El Niño, Agricultural and Veterinary Sciences, Plant Biology & Botany, Plant biology
Abstract

Tropical forests absorb large amounts of atmospheric CO2 through photosynthesis but elevated temperatures suppress this absorption and promote monoterpene emissions. Using 13 CO2 labeling, here we show that monoterpene emissions from tropical leaves derive from recent photosynthesis and demonstrate distinct temperature optima for five groups (Groups 1-5), potentially corresponding to different enzymatic temperature-dependent reaction mechanisms within β-ocimene synthases. As diurnal and seasonal leaf temperatures increased during the Amazonian 2015 El Niño event, leaf and landscape monoterpene emissions showed strong linear enrichments of β-ocimenes (+4.4% °C-1 ) at the expense of other monoterpene isomers. The observed inverse temperature response of α-pinene (-0.8% °C-1 ), typically assumed to be the dominant monoterpene with moderate reactivity, was not accurately simulated by current global emission models. Given that β-ocimenes are highly reactive with respect to both atmospheric and biological oxidants, the results suggest that highly reactive β-ocimenes may play important roles in the thermotolerance of photosynthesis by functioning as effective antioxidants within plants and as efficient atmospheric precursors of secondary organic aerosols. Thus, monoterpene composition may represent a new sensitive 'thermometer' of leaf oxidative stress and atmospheric reactivity, and therefore a new tool in future studies of warming impacts on tropical biosphere-atmosphere carbon-cycle feedbacks.

Published
2017

8. Reimagining Earth in the Earth System.

Author

Bonan, Gordon B., Lucier, Oliver, Coen, Deborah R., Foster, Adrianna C., Shuman, Jacquelyn K., Laguë, Marysa M., Swann, Abigail L. S., Lombardozzi, Danica L., Wieder, William R., Dahlin, Kyla M., Rocha, Adrian V., and SanClements, Michael D.

Subjects
CLIMATE change models, CLIMATE change, CLIMATE change mitigation, CLIMATOLOGY, BIOSPHERE, ATMOSPHERIC models
Abstract

Terrestrial, aquatic, and marine ecosystems regulate climate at local to global scales through exchanges of energy and matter with the atmosphere and assist with climate change mitigation through nature‐based climate solutions. Climate science is no longer a study of the physics of the atmosphere and oceans, but also the ecology of the biosphere. This is the promise of Earth system science: to transcend academic disciplines to enable study of the interacting physics, chemistry, and biology of the planet. However, long‐standing tension in protecting, restoring, and managing forest ecosystems to purposely improve climate evidences the difficulties of interdisciplinary science. For four centuries, forest management for climate betterment was argued, legislated, and ultimately dismissed, when nineteenth century atmospheric scientists narrowly defined climate science to the exclusion of ecology. Today's Earth system science, with its roots in global models of climate, unfolds in similar ways to the past. With Earth system models, geoscientists are again defining the ecology of the Earth system. Here we reframe Earth system science so that the biosphere and its ecology are equally integrated with the fluid Earth to enable Earth system prediction for planetary stewardship. Central to this is the need to overcome an intellectual heritage to the models that elevates geoscience and marginalizes ecology and local land knowledge. The call for kilometer‐scale atmospheric and ocean models, without concomitant scientific and computational investment in the land and biosphere, perpetuates the geophysical view of Earth and will not fully provide the comprehensive actionable information needed for a changing climate. Plain Language Summary: Terrestrial ecosystems provide a natural solution to planetary warming by storing carbon, dissipating surface heating through evapotranspiration, and other processes. That forests, in particular, influence climate is a centuries‐old premise, but its potential for planetary stewardship has not been realized. In an acrimonious controversy spanning several centuries, managing forests to purposely change climate was advocated, legislated, and resoundingly dismissed as unscientific. Similar intellectual bias is evident in today's Earth system science and the associated Earth system models, which are the state‐of‐the‐art models used to inform climate policy. The popular characterization of Earth system science lauds its interdisciplinary melding of physics, chemistry, and biology, but the models emphasize the physics and fluid dynamics of the atmosphere and oceans and present a limited perspective of terrestrial ecosystems in the Earth system. Ecologists studying the living world increasingly have a voice in Earth system science as we move beyond the physical basis for climate change to Earth system prediction for planetary stewardship. As we once again look to forests to solve a climate problem, we must surmount the disciplinary narrowness that failed to answer the forest‐climate question in the past and that continues to limit the interdisciplinary potential of Earth system science. Key Points: Nature‐based climate solutions have been advocated for centuries, but have been distorted by academic bias and colonialist prejudiceEarth system science, while recognizing the climate services of the biosphere, has a geophysical bias in interdisciplinary collaborationTo realize the potential for planetary stewardship, Earth system models must embrace the living world equally with the fluid world [ABSTRACT FROM AUTHOR]

Published
2024
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10. Towards a multiscale crop modelling framework for climate change adaptation assessment

Author

Peng, Bin, Guan, Kaiyu, Tang, Jinyun, Ainsworth, Elizabeth A., Asseng, Senthold, Bernacchi, Carl J., Cooper, Mark, Delucia, Evan H., Elliott, Joshua W., Ewert, Frank, Grant, Robert F., Gustafson, David I, Hammer, Graeme L., Jin, Zhenong, Jones, James W., Kimm, Hyungsuk, Lawrence, David M., Li, Yan, Lombardozzi, Danica L., Marshall-Colon, Amy, Messina, Carlos D., Ort, Donald R., Schnable, James C., Vallejos, C. Eduardo, Wu, Alex, Yin, Xinyou, and Zhou, Wang

Published
2020
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12. Overcoming barriers to enable convergence research by integrating ecological and climate sciences: the NCAR–NEON system Version 1

Author

Lombardozzi, Danica L., primary, Wieder, William R., additional, Sobhani, Negin, additional, Bonan, Gordon B., additional, Durden, David, additional, Lenz, Dawn, additional, SanClements, Michael, additional, Weintraub-Leff, Samantha, additional, Ayres, Edward, additional, Florian, Christopher R., additional, Dahlin, Kyla, additional, Kumar, Sanjiv, additional, Swann, Abigail L. S., additional, Zarakas, Claire M., additional, Vardeman, Charles, additional, and Pascucci, Valerio, additional

Published
2023
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15. Observation-based sowing dates and cultivars significantly affect yield and irrigation for some crops in the Community Land Model (CLM5).

Author

Rabin, Sam S., Sacks, William J., Lombardozzi, Danica L., Xia, Lili, and Robock, Alan

Subjects
SOWING, CULTIVARS, CROP management, CROPS, WHEAT, AGRICULTURE, SUGARCANE
Abstract

Farmers around the world time the planting of their crops to optimize growing season conditions and choose varieties that grow slowly enough to take advantage of the entire growing season while minimizing the risk of late-season kill. As climate changes, these strategies will be an important component of agricultural adaptation. Thus, it is critical that the global models used to project crop productivity under future conditions are able to realistically simulate growing season timing. This is especially important for climate- and hydrosphere-coupled crop models, where the intra-annual timing of crop growth and management affects regional weather and water availability. We have improved the crop module of the Community Land Model (CLM) to allow the use of externally specified crop planting dates and maturity requirements. In this way, CLM can use alternative algorithms for future crop calendars that are potentially more accurate and/or flexible than the built-in methods. Using observation-derived planting and maturity inputs reduces bias in the mean simulated global yield of sugarcane and cotton but increases bias for corn, spring wheat, and especially rice. These inputs also reduce simulated global irrigation demand by 15 %, much of which is associated with particular regions of corn and rice cultivation. Finally, we discuss how our results suggest areas for improvement in CLM and, potentially, similar crop models. [ABSTRACT FROM AUTHOR]

Published
2023
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16. Supplementary material to "Overcoming barriers to enable convergence research by integrating ecological and climate sciences: The NCAR-NEON system Version 1"

Author

Lombardozzi, Danica L., primary, Wieder, William R., additional, Sobhani, Negin, additional, Bonan, Gordon B., additional, Durden, David, additional, Lenz, Dawn, additional, SanClements, Michael, additional, Weintraub-Leff, Samantha, additional, Ayres, Edward, additional, Florian, Christopher R., additional, Dahlin, Kyla, additional, Kumar, Sanjiv, additional, Swann, Abigail L. S., additional, Zarakas, Claire, additional, Vardeman, Charles, additional, and Pascucci, Valerio, additional

Published
2023
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17. Is destabilisation risk increasing in land carbon sinks?

Author

Fernández-Martínez, Marcos, primary, Peñuelas, Josep, additional, Chevallier, Frederic, additional, Ciais, Philippe, additional, Obersteiner, Michael, additional, Rödenbeck, Christian, additional, Sardans, Jordi, additional, Vicca, Sara, additional, Yang, Hui, additional, Sitch, Stephen, additional, Friedlingstein, Pierre, additional, Arora, Vivek K., additional, Goll, Daniel, additional, Jain, Atul K., additional, Lombardozzi, Danica L., additional, and McGuire, Patrick C., additional

Published
2023
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18. Linking global terrestrial CO2 fluxes and environmental drivers: inferences from the Orbiting Carbon Observatory 2 satellite and terrestrial biospheric models

Author

Chen, Zichong, Liu, Junjie, Henze, Daven K., Huntzinger, Deborah N., Wells, Kelley C., Sitch, Stephen, Friedlingstein, Pierre, Joetzjer, Emilie, Bastrikov, Vladislav, Goll, Daniel S., Haverd, Vanessa, Jain, Atul K., Kato, Etsushi, Lienert, Sebastian, Lombardozzi, Danica L., McGuire, Patrick C., Melton, Joe R., Nabel, Julia E. M. S., Poulter, Benjamin, Tian, Hanqin, Wiltshire, Andrew J., Zaehle, Sönke, and Miller, Scot M.

Subjects
Chemistry, Physics, QC1-999, QD1-999
Abstract

Observations from the Orbiting Carbon Observatory 2 (OCO-2) satellite have been used to estimate CO2 fluxes in many regions of the globe and provide new insight into the global carbon cycle. The objective of this study is to infer the relationships between patterns in OCO-2 observations and environmental drivers (e.g., temperature, precipitation) and therefore inform a process understanding of carbon fluxes using OCO-2. We use a multiple regression and inverse model, and the regression coefficients quantify the relationships between observations from OCO-2 and environmental driver datasets within individual years for 2015–2018 and within seven global biomes. We subsequently compare these inferences to the relationships estimated from 15 terrestrial biosphere models (TBMs) that participated in the TRENDY model inter-comparison. Using OCO-2, we are able to quantify only a limited number of relationships between patterns in atmospheric CO2 observations and patterns in environmental driver datasets (i.e., 10 out of the 42 relationships examined). We further find that the ensemble of TBMs exhibits a large spread in the relationships with these key environmental driver datasets. The largest uncertainty in the models is in the relationship with precipitation, particularly in the tropics, with smaller uncertainties for temperature and photosynthetically active radiation (PAR). Using observations from OCO-2, we find that precipitation is associated with increased CO2 uptake in all tropical biomes, a result that agrees with half of the TBMs. By contrast, the relationships that we infer from OCO-2 for temperature and PAR are similar to the ensemble mean of the TBMs, though the results differ from many individual TBMs. These results point to the limitations of current space-based observations for inferring environmental relationships but also indicate the potential to help inform key relationships that are very uncertain in state-of-the-art TBMs.

Published
2021

20. Overcoming barriers to enable convergence research by integrating ecological and climate sciences: The NCAR-NEON system Version 1.

Author

Lombardozzi, Danica L., Wieder, William R., Sobhani, Negin, Bonan, Gordon B., Durden, David, Lenz, Dawn, SanClements, Michael, Weintraub-Leff, Samantha, Ayres, Edward, Florian, Christopher R., Dahlin, Kyla, Kumar, Sanjiv, Swann, Abigail L. S., Zarakas, Claire, Vardeman, Charles, and Pascucci, Valerio

Subjects
CLIMATOLOGY, EARTH system science, SYSTEMS theory, USER interfaces, CYBERINFRASTRUCTURE, BIOSPHERE
Abstract

Global change research demands a convergence among academic disciplines to understand complex changes in Earth system function. Limitations related to data usability and computing infrastructure, however, present barriers to effective use of the research tools needed for this cross-disciplinary collaboration. To address these barriers, we created a computational platform that pairs meteorological data and site-level ecosystem characterizations from the National Ecological Observatory Network (NEON) with the Community Terrestrial System Model (CTSM) that is developed with university partners at the National Center for Atmospheric Research (NCAR). This NCAR-NEON system features a simplified user interface that facilitates access to and use of NEON observations and NCAR models. We present preliminary results that compare observed NEON fluxes with CTSM simulations and describe how the collaboration between NCAR and NEON that can be used by the global change research community improves both the data and model. Beyond datasets and computing, the NCAR-NEON system includes tutorials and visualization tools that facilitate interaction with observational and model datasets and further enable opportunities for teaching and research. By expanding access to data, models, and computing, cyberinfrastructure tools like the NCAR-NEON system will accelerate integration across ecology and climate science disciplines to advance understanding in Earth system science and global change. [ABSTRACT FROM AUTHOR]

Published
2023
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21. Ubiquity of human-induced changes in climate variability

Author

Rodgers, Keith B., primary, Lee, Sun-Seon, additional, Rosenbloom, Nan, additional, Timmermann, Axel, additional, Danabasoglu, Gokhan, additional, Deser, Clara, additional, Edwards, Jim, additional, Kim, Ji-Eun, additional, Simpson, Isla R., additional, Stein, Karl, additional, Stuecker, Malte F., additional, Yamaguchi, Ryohei, additional, Bódai, Tamás, additional, Chung, Eui-Seok, additional, Huang, Lei, additional, Kim, Who M., additional, Lamarque, Jean-François, additional, Lombardozzi, Danica L., additional, Wieder, William R., additional, and Yeager, Stephen G., additional

Published
2021
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22. Increasing the spatial and temporal impact of ecological research: A roadmap for integrating a novel terrestrial process into an Earth system model

Author

Kyker‐Snowman, Emily, primary, Lombardozzi, Danica L., additional, Bonan, Gordon B., additional, Cheng, Susan J., additional, Dukes, Jeffrey S., additional, Frey, Serita D., additional, Jacobs, Elin M., additional, McNellis, Risa, additional, Rady, Joshua M., additional, Smith, Nicholas G., additional, Thomas, R. Quinn, additional, Wieder, William R., additional, and Grandy, A. Stuart, additional

Published
2021
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24. Dynamic global vegetation models underestimate net CO2 flux mean and inter-annual variability in dryland ecosystems

Author

MacBean, Natasha, primary, Scott, Russell L, additional, Biederman, Joel A, additional, Peylin, Philippe, additional, Kolb, Thomas, additional, Litvak, Marcy E, additional, Krishnan, Praveena, additional, Meyers, Tilden P, additional, Arora, Vivek K, additional, Bastrikov, Vladislav, additional, Goll, Daniel, additional, Lombardozzi, Danica L, additional, Nabel, Julia E M S, additional, Pongratz, Julia, additional, Sitch, Stephen, additional, Walker, Anthony P, additional, Zaehle, Sönke, additional, and Moore, David J P, additional

Published
2021
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25. Behavioral responses of the endemic shrimp Halocaridina rubra (Malacostraca: Atyidae) to an introduced fish, Gambusia affinis (Actinopterygii: Poeciliidae) and implications for the trophic structure of Hawaiian anchialine ponds

Author

Capps, Krista A., Turner, Caroline B., Booth, Michael T., Lombardozzi, Danica L., McArt, Scott H., Chai, David, and Hairston, Jr., Nelson G.

Subjects
Hawaii -- Natural resources, Shrimps -- Behavior -- Environmental aspects, Earth sciences, Science and technology
Abstract

Abstract: In the Hawaiian Islands, intentionally introduced exotic fishes have been linked to changes in native biodiversity and community composition. In 1905, the mosquito fish Gambusia affinis was introduced to [...]

Published
2009

27. Five years of variability in the global carbon cycle: comparing an estimate from the Orbiting Carbon Observatory-2 and process-based models

Author

Chen, Zichong, primary, Huntzinger, Deborah N, additional, Liu, Junjie, additional, Piao, Shilong, additional, Wang, Xuhui, additional, Sitch, Stephen, additional, Friedlingstein, Pierre, additional, Anthoni, Peter, additional, Arneth, Almut, additional, Bastrikov, Vladislav, additional, Goll, Daniel S, additional, Haverd, Vanessa, additional, Jain, Atul K, additional, Joetzjer, Emilie, additional, Kato, Etsushi, additional, Lienert, Sebastian, additional, Lombardozzi, Danica L, additional, McGuire, Patrick C, additional, Melton, Joe R, additional, Nabel, Julia E M S, additional, Pongratz, Julia, additional, Poulter, Benjamin, additional, Tian, Hanqin, additional, Wiltshire, Andrew J, additional, Zaehle, Sönke, additional, and Miller, Scot M, additional

Published
2021
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28. Modest capacity of no-till farming to offset emissions over 21st century

Author

Graham, Michael W., Thomas, R. Quinn, Lombardozzi, Danica L., O'Rourke, Megan E., Graham, Michael W., Thomas, R. Quinn, Lombardozzi, Danica L., and O'Rourke, Megan E.

Abstract

'No-till' (NT) agriculture, which eliminates nearly all physical disturbance of the soil surface on croplands, has been widely promoted as a means of soil organic carbon (SOC) sequestration with the potential to mitigate climate change. Here we provide the first global estimates of the SOC sequestration potential of NT adoption using a global land surface model (LSM). We use an LSM to simulate losses of SOC due to intensive tillage (IT) over the historical time period (1850-2014), followed by future simulations (2015-2100) assessing the SOC sequestration potential of adopting NT globally. Historical losses due to simulated IT practices ranged from 6.8 to 16.8 Gt C, or roughly 5%-13% of the 133 Gt C of global cumulative SOC losses attributable to agriculture reported elsewhere. Cumulative SOC sequestration in NT simulations over the entire 21st century was equivalent to approximately one year of current fossil fuel emissions and ranged between 6.6 and 14.4 Gt C (0.08-0.17 Gt C yr-1). Modeled increases in SOC sequestration under NT were concentrated in cool, humid temperate regions, with minimal SOC gains in the tropics. These results indicate that the global potential for SOC sequestration from NT adoption may be more limited than reported in some studies and promoted by policymakers. Our incorporation of tillage practices into an LSM is a major step toward integration of soil tillage as a management practice into LSMs and associated Earth system models. Future work should focus on improving process-understanding of tillage practices and their integration into LSMs, as well as resolving modeled versus observed estimates of SOC sequestration from NT adoption, particularly in the tropics.

Published
2021
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29. Increasing the spatial and temporal impact of ecological research: A roadmap for integrating a novel terrestrial process into an Earth system model

Author

Kyker-Snowman, Emily, Lombardozzi, Danica L., Bonan, Gordon B., Cheng, Susan J., Dukes, Jeffrey S., Frey, Serita D., Jacobs, Elin M., McNellis, Risa, Rady, Joshua M., Smith, Nicholas G., Thomas, R. Quinn, Wieder, William W., Grandy, A. Stuart, Kyker-Snowman, Emily, Lombardozzi, Danica L., Bonan, Gordon B., Cheng, Susan J., Dukes, Jeffrey S., Frey, Serita D., Jacobs, Elin M., McNellis, Risa, Rady, Joshua M., Smith, Nicholas G., Thomas, R. Quinn, Wieder, William W., and Grandy, A. Stuart

Abstract

Terrestrial ecosystems regulate Earth's climate through water, energy, and biogeochemical transformations. Despite a key role in regulating the Earth system, terrestrial ecology has historically been underrepresented in the Earth system models (ESMs) that are used to understand and project global environmental change. Ecology and Earth system modeling must be integrated for scientists to fully comprehend the role of ecological systems in driving and responding to global change. Ecological insights can improve ESM realism and reduce process uncertainty, while ESMs offer ecologists an opportunity to broadly test ecological theory and increase the impact of their work by scaling concepts through time and space. Despite this mutualism, meaningfully integrating the two remains a persistent challenge, in part because of logistical obstacles in translating processes into mathematical formulas and identifying ways to integrate new theories and code into large, complex model structures. To help overcome this interdisciplinary challenge, we present a framework consisting of a series of interconnected stages for integrating a new ecological process or insight into an ESM. First, we highlight the multiple ways that ecological observations and modeling iteratively strengthen one another, dispelling the illusion that the ecologist's role ends with initial provision of data. Second, we show that many valuable insights, products, and theoretical developments are produced through sustained interdisciplinary collaborations between empiricists and modelers, regardless of eventual inclusion of a process in an ESM. Finally, we provide concrete actions and resources to facilitate learning and collaboration at every stage of data-model integration. This framework will create synergies that will transform our understanding of ecology within the Earth system, ultimately improving our understanding of global environmental change and broadening the impact of ecological research.

Published
2021
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30. Increasing the spatial and temporal impact of ecological research: A roadmap for integrating a novel terrestrial process into an Earth system model

Author

Forest Resources and Environmental Conservation, Kyker-Snowman, Emily, Lombardozzi, Danica L., Bonan, Gordon B., Cheng, Susan J., Dukes, Jeffrey S., Frey, Serita D., Jacobs, Elin M., McNellis, Risa, Rady, Joshua M., Smith, Nicholas G., Thomas, R. Quinn, Wieder, William W., Grandy, A. Stuart, Forest Resources and Environmental Conservation, Kyker-Snowman, Emily, Lombardozzi, Danica L., Bonan, Gordon B., Cheng, Susan J., Dukes, Jeffrey S., Frey, Serita D., Jacobs, Elin M., McNellis, Risa, Rady, Joshua M., Smith, Nicholas G., Thomas, R. Quinn, Wieder, William W., and Grandy, A. Stuart

Abstract

Terrestrial ecosystems regulate Earth's climate through water, energy, and biogeochemical transformations. Despite a key role in regulating the Earth system, terrestrial ecology has historically been underrepresented in the Earth system models (ESMs) that are used to understand and project global environmental change. Ecology and Earth system modeling must be integrated for scientists to fully comprehend the role of ecological systems in driving and responding to global change. Ecological insights can improve ESM realism and reduce process uncertainty, while ESMs offer ecologists an opportunity to broadly test ecological theory and increase the impact of their work by scaling concepts through time and space. Despite this mutualism, meaningfully integrating the two remains a persistent challenge, in part because of logistical obstacles in translating processes into mathematical formulas and identifying ways to integrate new theories and code into large, complex model structures. To help overcome this interdisciplinary challenge, we present a framework consisting of a series of interconnected stages for integrating a new ecological process or insight into an ESM. First, we highlight the multiple ways that ecological observations and modeling iteratively strengthen one another, dispelling the illusion that the ecologist's role ends with initial provision of data. Second, we show that many valuable insights, products, and theoretical developments are produced through sustained interdisciplinary collaborations between empiricists and modelers, regardless of eventual inclusion of a process in an ESM. Finally, we provide concrete actions and resources to facilitate learning and collaboration at every stage of data-model integration. This framework will create synergies that will transform our understanding of ecology within the Earth system, ultimately improving our understanding of global environmental change and broadening the impact of ecological research.

Published
2021

31. Modest capacity of no-till farming to offset emissions over 21st century

Author

Forest Resources and Environmental Conservation, Graham, Michael W., Thomas, R. Quinn, Lombardozzi, Danica L., O'Rourke, Megan E., Forest Resources and Environmental Conservation, Graham, Michael W., Thomas, R. Quinn, Lombardozzi, Danica L., and O'Rourke, Megan E.

Abstract

'No-till' (NT) agriculture, which eliminates nearly all physical disturbance of the soil surface on croplands, has been widely promoted as a means of soil organic carbon (SOC) sequestration with the potential to mitigate climate change. Here we provide the first global estimates of the SOC sequestration potential of NT adoption using a global land surface model (LSM). We use an LSM to simulate losses of SOC due to intensive tillage (IT) over the historical time period (1850-2014), followed by future simulations (2015-2100) assessing the SOC sequestration potential of adopting NT globally. Historical losses due to simulated IT practices ranged from 6.8 to 16.8 Gt C, or roughly 5%-13% of the 133 Gt C of global cumulative SOC losses attributable to agriculture reported elsewhere. Cumulative SOC sequestration in NT simulations over the entire 21st century was equivalent to approximately one year of current fossil fuel emissions and ranged between 6.6 and 14.4 Gt C (0.08-0.17 Gt C yr-1). Modeled increases in SOC sequestration under NT were concentrated in cool, humid temperate regions, with minimal SOC gains in the tropics. These results indicate that the global potential for SOC sequestration from NT adoption may be more limited than reported in some studies and promoted by policymakers. Our incorporation of tillage practices into an LSM is a major step toward integration of soil tillage as a management practice into LSMs and associated Earth system models. Future work should focus on improving process-understanding of tillage practices and their integration into LSMs, as well as resolving modeled versus observed estimates of SOC sequestration from NT adoption, particularly in the tropics.

Published
2021

38. Dry deposition of ozone over land: processes, measurement, and modeling

Author

Clifton, Olivia E., Fiore, Arlene M., Massman, William J., Baublitz, Colleen B., Coyle, Mhairi, Emberson, Lisa, Fares, Silvano, Farmer, Delphine K., Gentine, Pierre, Gerosa, Giacomo, Guenther, Alex B., Helmig, Detlev, Lombardozzi, Danica L., Munger, J. William, Patton, Edward G., Pusede, Sally E., Schwede, Donna B., Silva, Sam J., Sörgel, Matthias, Steiner, Allison L., Tai, Amos P.K., Clifton, Olivia E., Fiore, Arlene M., Massman, William J., Baublitz, Colleen B., Coyle, Mhairi, Emberson, Lisa, Fares, Silvano, Farmer, Delphine K., Gentine, Pierre, Gerosa, Giacomo, Guenther, Alex B., Helmig, Detlev, Lombardozzi, Danica L., Munger, J. William, Patton, Edward G., Pusede, Sally E., Schwede, Donna B., Silva, Sam J., Sörgel, Matthias, Steiner, Allison L., and Tai, Amos P.K.

Abstract

Dry deposition of ozone is an important sink of ozone in near‐surface air. When dry deposition occurs through plant stomata, ozone can injure the plant, altering water and carbon cycling and reducing crop yields. Quantifying both stomatal and nonstomatal uptake accurately is relevant for understanding ozone's impact on human health as an air pollutant and on climate as a potent short‐lived greenhouse gas and primary control on the removal of several reactive greenhouse gases and air pollutants. Robust ozone dry deposition estimates require knowledge of the relative importance of individual deposition pathways, but spatiotemporal variability in nonstomatal deposition is poorly understood. Here we integrate understanding of ozone deposition processes by synthesizing research from fields such as atmospheric chemistry, ecology, and meteorology. We critically review methods for measurements and modeling, highlighting the empiricism that underpins modeling and thus the interpretation of observations. Our unprecedented synthesis of knowledge on deposition pathways, particularly soil and leaf cuticles, reveals process understanding not yet included in widely used models. If coordinated with short‐term field intensives, laboratory studies, and mechanistic modeling, measurements from a few long‐term sites would bridge the molecular to ecosystem scales necessary to establish the relative importance of individual deposition pathways and the extent to which they vary in space and time. Our recommended approaches seek to close knowledge gaps that currently limit quantifying the impact of ozone dry deposition on air quality, ecosystems, and climate.

Published
2020

39. Increasing the spatial and temporal impact of ecological research: A roadmap for integrating a novel terrestrial process into an Earth system model.

Author

Kyker‐Snowman, Emily, Lombardozzi, Danica L., Bonan, Gordon B., Cheng, Susan J., Dukes, Jeffrey S., Frey, Serita D., Jacobs, Elin M., McNellis, Risa, Rady, Joshua M., Smith, Nicholas G., Thomas, R. Quinn, Wieder, William R., and Grandy, A. Stuart

Subjects
*ECOLOGICAL impact, *GLOBAL environmental change, *CARBON cycle, *ECOSYSTEMS, *MATHEMATICAL formulas, *ECOLOGICAL models
Abstract

Terrestrial ecosystems regulate Earth's climate through water, energy, and biogeochemical transformations. Despite a key role in regulating the Earth system, terrestrial ecology has historically been underrepresented in the Earth system models (ESMs) that are used to understand and project global environmental change. Ecology and Earth system modeling must be integrated for scientists to fully comprehend the role of ecological systems in driving and responding to global change. Ecological insights can improve ESM realism and reduce process uncertainty, while ESMs offer ecologists an opportunity to broadly test ecological theory and increase the impact of their work by scaling concepts through time and space. Despite this mutualism, meaningfully integrating the two remains a persistent challenge, in part because of logistical obstacles in translating processes into mathematical formulas and identifying ways to integrate new theories and code into large, complex model structures. To help overcome this interdisciplinary challenge, we present a framework consisting of a series of interconnected stages for integrating a new ecological process or insight into an ESM. First, we highlight the multiple ways that ecological observations and modeling iteratively strengthen one another, dispelling the illusion that the ecologist's role ends with initial provision of data. Second, we show that many valuable insights, products, and theoretical developments are produced through sustained interdisciplinary collaborations between empiricists and modelers, regardless of eventual inclusion of a process in an ESM. Finally, we provide concrete actions and resources to facilitate learning and collaboration at every stage of data‐model integration. This framework will create synergies that will transform our understanding of ecology within the Earth system, ultimately improving our understanding of global environmental change, and broadening the impact of ecological research. [ABSTRACT FROM AUTHOR]

Published
2022
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43. Decadal fates and impacts of nitrogen additions on temperate forest carbon storage: a data–model comparison

Author

Cheng, Susan J., primary, Hess, Peter G., additional, Wieder, William R., additional, Thomas, R. Quinn, additional, Nadelhoffer, Knute J., additional, Vira, Julius, additional, Lombardozzi, Danica L., additional, Gundersen, Per, additional, Fernandez, Ivan J., additional, Schleppi, Patrick, additional, Gruselle, Marie-Cécile, additional, Moldan, Filip, additional, and Goodale, Christine L., additional

Published
2019
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44. The Community Land Model Version 5: Description of New Features, Benchmarking, and Impact of Forcing Uncertainty

Author

Lawrence, David M., Fisher, Rosie A., Koven, Charles D., Oleson, Keith W., Swenson, Sean C., Bonan, Gordon B., Collier, Nathan, Ghimire, Bardan, van Kampenhout, Leo, Kennedy, Daniel, Kluzek, Erik, Lawrence, Peter J., Li, Fang, Li, Hongyi, Lombardozzi, Danica L., Riley, William J., Sacks, William J., Shi, Mingjie, Vertenstein, Mariana, Wieder, William R., Xu, Chonggang, Ali, Ashehad A., Badger, Andrew M., Bisht, Gautam, van den Broeke, Michiel, Brunke, Michael A., Burns, Sean P., Buzan, Jonathan, Clark, Martyn, Craig, Anthony, Dahlin, Kyla, Drewniak, Beth, Fisher, Joshua B., Flanner, Mark, Fox, Andrew M., Gentine, Pierre, Hoffman, Forrest, Keppel-Aleks, Gretchen, Knox, Ryan, Kumar, Sanjiv, Lenaerts, Jan, Leung, L. Ruby, Lipscomb, William H., Lu, Yaqiong, Pandey, Ashutosh, Pelletier, Jon D., Perket, Justin, Randerson, James T., Ricciuto, Daniel M., Sanderson, Benjamin M., Slater, Andrew, Subin, Zachary M., Tang, Jinyun, Thomas, R. Quinn, Martin, Maria Val, Zeng, Xubin, Lawrence, David M., Fisher, Rosie A., Koven, Charles D., Oleson, Keith W., Swenson, Sean C., Bonan, Gordon B., Collier, Nathan, Ghimire, Bardan, van Kampenhout, Leo, Kennedy, Daniel, Kluzek, Erik, Lawrence, Peter J., Li, Fang, Li, Hongyi, Lombardozzi, Danica L., Riley, William J., Sacks, William J., Shi, Mingjie, Vertenstein, Mariana, Wieder, William R., Xu, Chonggang, Ali, Ashehad A., Badger, Andrew M., Bisht, Gautam, van den Broeke, Michiel, Brunke, Michael A., Burns, Sean P., Buzan, Jonathan, Clark, Martyn, Craig, Anthony, Dahlin, Kyla, Drewniak, Beth, Fisher, Joshua B., Flanner, Mark, Fox, Andrew M., Gentine, Pierre, Hoffman, Forrest, Keppel-Aleks, Gretchen, Knox, Ryan, Kumar, Sanjiv, Lenaerts, Jan, Leung, L. Ruby, Lipscomb, William H., Lu, Yaqiong, Pandey, Ashutosh, Pelletier, Jon D., Perket, Justin, Randerson, James T., Ricciuto, Daniel M., Sanderson, Benjamin M., Slater, Andrew, Subin, Zachary M., Tang, Jinyun, Thomas, R. Quinn, Martin, Maria Val, and Zeng, Xubin

Abstract

The Community Land Model (CLM) is the land component of the Community Earth System Model (CESM) and is used in several global and regional modeling systems. In this paper, we introduce model developments included in CLM version 5 (CLM5), which is the default land component for CESM2. We assess an ensemble of simulations, including prescribed and prognostic vegetation state, multiple forcing data sets, and CLM4, CLM4.5, and CLM5, against a range of metrics including from the International Land Model Benchmarking (ILAMBv2) package. CLM5 includes new and updated processes and parameterizations: (1) dynamic land units, (2) updated parameterizations and structure for hydrology and snow (spatially explicit soil depth, dry surface layer, revised groundwater scheme, revised canopy interception and canopy snow processes, updated fresh snow density, simple firn model, and Model for Scale Adaptive River Transport), (3) plant hydraulics and hydraulic redistribution, (4) revised nitrogen cycling (flexible leaf stoichiometry, leaf N optimization for photosynthesis, and carbon costs for plant nitrogen uptake), (5) global crop model with six crop types and time-evolving irrigated areas and fertilization rates, (6) updated urban building energy, (7) carbon isotopes, and (8) updated stomatal physiology. New optional features include demographically structured dynamic vegetation model (Functionally Assembled Terrestrial Ecosystem Simulator), ozone damage to plants, and fire trace gas emissions coupling to the atmosphere. Conclusive establishment of improvement or degradation of individual variables or metrics is challenged by forcing uncertainty, parametric uncertainty, and model structural complexity, but the multivariate metrics presented here suggest a general broad improvement from CLM4 to CLM5.

Published
2019
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45. Decadal fates and impacts of nitrogen additions on temperate forest carbon storage: a data-model comparison

Author

Cheng, Susan J., Hess, Peter G., Wieder, William R., Thomas, R. Quinn, Nadelhoffer, Knute J., Vira, Julius, Lombardozzi, Danica L., Gundersen, Per, Fernandez, Ivan J., Schleppi, Patrick, Gruselle, Marie-Cecile, Moldan, Filip, Goodale, Christine L., Cheng, Susan J., Hess, Peter G., Wieder, William R., Thomas, R. Quinn, Nadelhoffer, Knute J., Vira, Julius, Lombardozzi, Danica L., Gundersen, Per, Fernandez, Ivan J., Schleppi, Patrick, Gruselle, Marie-Cecile, Moldan, Filip, and Goodale, Christine L.

Abstract

To accurately capture the impacts of nitrogen (N) on the land carbon (C) sink in Earth system models, model responses to both N limitation and ecosystem N additions (e.g., from atmospheric N deposition and fertilizer) need to be evaluated. The response of the land C sink to N additions depends on the fate of these additions: that is, how much of the added N is lost from the ecosystem through N loss pathways or recovered and used to increase C storage in plants and soils. Here, we evaluate the C-N dynamics of the latest version of a global land model, the Community Land Model version 5 (CLM5), and how they vary when ecosystems have large N inputs and losses (i.e., an open N cycle) or small N inputs and losses (i.e., a closed N cycle). This comparison allows us to identify potential improvements to CLM5 that would apply to simulated N cycles along the open-to-closed spectrum. We also compare the short-(< 3 years) and longerterm (5-17 years) N fates in CLM5 against observations from 13 long-term 15N tracer addition experiments at eight temperate forest sites. Simulations using both open and closed N cycles overestimated plant N recovery following N additions. In particular, the model configuration with a closed N cycle simulated that plants acquired more than twice the amount of added N recovered in 15N tracer studies on short timescales (CLM5: 46 ± 12 %; observations: 18 ± 12 %; mean across sites ±1 standard deviation) and almost twice as much on longer timescales (CLM5: 23±6 %; observations: 13±5 %). Soil N recoveries in simulations with closed N cycles were closer to observations in the short term (CLM5: 40 ± 10 %; observations: 54±22 %) but smaller than observations in the long term (CLM5: 59±15 %; observations: 69±18 %). Simulations with open N cycles estimated similar patterns in plant and soil N recovery, except that soil N recovery was also smaller than observations in the short term. In both open and closed sets of simulations, soil N recoveries in CLM5 occurr

Published
2019
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46. Beyond Static Benchmarking: Using Experimental Manipulations to Evaluate Land Model Assumptions

Author

Wieder, William R., Lawrence, David M., Fisher, Rosie A., Bonan, Gordon B., Cheng, Susan J., Goodale, Christine L., Grandy, A. Stuart, Koven, Charles D., Lombardozzi, Danica L., Oleson, Keith W., Thomas, R. Quinn, Wieder, William R., Lawrence, David M., Fisher, Rosie A., Bonan, Gordon B., Cheng, Susan J., Goodale, Christine L., Grandy, A. Stuart, Koven, Charles D., Lombardozzi, Danica L., Oleson, Keith W., and Thomas, R. Quinn

Abstract

Land models are often used to simulate terrestrial responses to future environmental changes, but these models are not commonly evaluated with data from experimental manipulations. Results from experimental manipulations can identify and evaluate model assumptions that are consistent with appropriate ecosystem responses to future environmental change. We conducted simulations using three coupled carbon-nitrogen versions of the Community Land Model (CLM, versions 4, 4.5, and—the newly developed—5), and compared the simulated response to nitrogen (N) and atmospheric carbon dioxide (CO2) enrichment with meta-analyses of observations from similar experimental manipulations. In control simulations, successive versions of CLM showed a poleward increase in gross primary productivity and an overall bias reduction, compared to FLUXNET-MTE observations. Simulations with N and CO2 enrichment demonstrate that CLM transitioned from a model that exhibited strong nitrogen limitation of the terrestrial carbon cycle (CLM4) to a model that showed greater responsiveness to elevated concentrations of CO2 in the atmosphere (CLM5). Overall, CLM5 simulations showed better agreement with observed ecosystem responses to experimental N and CO2 enrichment than previous versions of the model. These simulations also exposed shortcomings in structural assumptions and parameterizations. Specifically, no version of CLM captures changes in plant physiology, allocation, and nutrient uptake that are likely important aspects of terrestrial ecosystems' responses to environmental change. These highlight priority areas that should be addressed in future model developments. Moving forward, incorporating results from experimental manipulations into model benchmarking tools that are used to evaluate model performance will help increase confidence in terrestrial carbon cycle projections.

Published
2019
Full Text
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47. Decadal fates and impacts of nitrogen additions on temperate forest carbon storage: a data-model comparison

Author

Forest Resources and Environmental Conservation, Cheng, Susan J., Hess, Peter G., Wieder, William R., Thomas, R. Quinn, Nadelhoffer, Knute J., Vira, Julius, Lombardozzi, Danica L., Gundersen, Per, Fernandez, Ivan J., Schleppi, Patrick, Gruselle, Marie-Cecile, Moldan, Filip, Goodale, Christine L., Forest Resources and Environmental Conservation, Cheng, Susan J., Hess, Peter G., Wieder, William R., Thomas, R. Quinn, Nadelhoffer, Knute J., Vira, Julius, Lombardozzi, Danica L., Gundersen, Per, Fernandez, Ivan J., Schleppi, Patrick, Gruselle, Marie-Cecile, Moldan, Filip, and Goodale, Christine L.

Abstract

To accurately capture the impacts of nitrogen (N) on the land carbon (C) sink in Earth system models, model responses to both N limitation and ecosystem N additions (e.g., from atmospheric N deposition and fertilizer) need to be evaluated. The response of the land C sink to N additions depends on the fate of these additions: that is, how much of the added N is lost from the ecosystem through N loss pathways or recovered and used to increase C storage in plants and soils. Here, we evaluate the C-N dynamics of the latest version of a global land model, the Community Land Model version 5 (CLM5), and how they vary when ecosystems have large N inputs and losses (i.e., an open N cycle) or small N inputs and losses (i.e., a closed N cycle). This comparison allows us to identify potential improvements to CLM5 that would apply to simulated N cycles along the open-to-closed spectrum. We also compare the short-(< 3 years) and longerterm (5-17 years) N fates in CLM5 against observations from 13 long-term 15N tracer addition experiments at eight temperate forest sites. Simulations using both open and closed N cycles overestimated plant N recovery following N additions. In particular, the model configuration with a closed N cycle simulated that plants acquired more than twice the amount of added N recovered in 15N tracer studies on short timescales (CLM5: 46 ± 12 %; observations: 18 ± 12 %; mean across sites ±1 standard deviation) and almost twice as much on longer timescales (CLM5: 23±6 %; observations: 13±5 %). Soil N recoveries in simulations with closed N cycles were closer to observations in the short term (CLM5: 40 ± 10 %; observations: 54±22 %) but smaller than observations in the long term (CLM5: 59±15 %; observations: 69±18 %). Simulations with open N cycles estimated similar patterns in plant and soil N recovery, except that soil N recovery was also smaller than observations in the short term. In both open and closed sets of simulations, soil N recoveries in CLM5 occurr

Published
2019

48. The Community Land Model Version 5: Description of New Features, Benchmarking, and Impact of Forcing Uncertainty

Author

Forest Resources and Environmental Conservation, Lawrence, David M., Fisher, Rosie A., Koven, Charles D., Oleson, Keith W., Swenson, Sean C., Bonan, Gordon B., Collier, Nathan, Ghimire, Bardan, van Kampenhout, Leo, Kennedy, Daniel, Kluzek, Erik, Lawrence, Peter J., Li, Fang, Li, Hongyi, Lombardozzi, Danica L., Riley, William J., Sacks, William J., Shi, Mingjie, Vertenstein, Mariana, Wieder, William R., Xu, Chonggang, Ali, Ashehad A., Badger, Andrew M., Bisht, Gautam, van den Broeke, Michiel, Brunke, Michael A., Burns, Sean P., Buzan, Jonathan, Clark, Martyn, Craig, Anthony, Dahlin, Kyla, Drewniak, Beth, Fisher, Joshua B., Flanner, Mark, Fox, Andrew M., Gentine, Pierre, Hoffman, Forrest, Keppel-Aleks, Gretchen, Knox, Ryan, Kumar, Sanjiv, Lenaerts, Jan, Leung, L. Ruby, Lipscomb, William H., Lu, Yaqiong, Pandey, Ashutosh, Pelletier, Jon D., Perket, Justin, Randerson, James T., Ricciuto, Daniel M., Sanderson, Benjamin M., Slater, Andrew, Subin, Zachary M., Tang, Jinyun, Thomas, R. Quinn, Martin, Maria Val, Zeng, Xubin, Forest Resources and Environmental Conservation, Lawrence, David M., Fisher, Rosie A., Koven, Charles D., Oleson, Keith W., Swenson, Sean C., Bonan, Gordon B., Collier, Nathan, Ghimire, Bardan, van Kampenhout, Leo, Kennedy, Daniel, Kluzek, Erik, Lawrence, Peter J., Li, Fang, Li, Hongyi, Lombardozzi, Danica L., Riley, William J., Sacks, William J., Shi, Mingjie, Vertenstein, Mariana, Wieder, William R., Xu, Chonggang, Ali, Ashehad A., Badger, Andrew M., Bisht, Gautam, van den Broeke, Michiel, Brunke, Michael A., Burns, Sean P., Buzan, Jonathan, Clark, Martyn, Craig, Anthony, Dahlin, Kyla, Drewniak, Beth, Fisher, Joshua B., Flanner, Mark, Fox, Andrew M., Gentine, Pierre, Hoffman, Forrest, Keppel-Aleks, Gretchen, Knox, Ryan, Kumar, Sanjiv, Lenaerts, Jan, Leung, L. Ruby, Lipscomb, William H., Lu, Yaqiong, Pandey, Ashutosh, Pelletier, Jon D., Perket, Justin, Randerson, James T., Ricciuto, Daniel M., Sanderson, Benjamin M., Slater, Andrew, Subin, Zachary M., Tang, Jinyun, Thomas, R. Quinn, Martin, Maria Val, and Zeng, Xubin

Abstract

The Community Land Model (CLM) is the land component of the Community Earth System Model (CESM) and is used in several global and regional modeling systems. In this paper, we introduce model developments included in CLM version 5 (CLM5), which is the default land component for CESM2. We assess an ensemble of simulations, including prescribed and prognostic vegetation state, multiple forcing data sets, and CLM4, CLM4.5, and CLM5, against a range of metrics including from the International Land Model Benchmarking (ILAMBv2) package. CLM5 includes new and updated processes and parameterizations: (1) dynamic land units, (2) updated parameterizations and structure for hydrology and snow (spatially explicit soil depth, dry surface layer, revised groundwater scheme, revised canopy interception and canopy snow processes, updated fresh snow density, simple firn model, and Model for Scale Adaptive River Transport), (3) plant hydraulics and hydraulic redistribution, (4) revised nitrogen cycling (flexible leaf stoichiometry, leaf N optimization for photosynthesis, and carbon costs for plant nitrogen uptake), (5) global crop model with six crop types and time-evolving irrigated areas and fertilization rates, (6) updated urban building energy, (7) carbon isotopes, and (8) updated stomatal physiology. New optional features include demographically structured dynamic vegetation model (Functionally Assembled Terrestrial Ecosystem Simulator), ozone damage to plants, and fire trace gas emissions coupling to the atmosphere. Conclusive establishment of improvement or degradation of individual variables or metrics is challenged by forcing uncertainty, parametric uncertainty, and model structural complexity, but the multivariate metrics presented here suggest a general broad improvement from CLM4 to CLM5.

Published
2019

49. Beyond Static Benchmarking: Using Experimental Manipulations to Evaluate Land Model Assumptions

Author

Forest Resources and Environmental Conservation, Wieder, William R., Lawrence, David M., Fisher, Rosie A., Bonan, Gordon B., Cheng, Susan J., Goodale, Christine L., Grandy, A. Stuart, Koven, Charles D., Lombardozzi, Danica L., Oleson, Keith W., Thomas, R. Quinn, Forest Resources and Environmental Conservation, Wieder, William R., Lawrence, David M., Fisher, Rosie A., Bonan, Gordon B., Cheng, Susan J., Goodale, Christine L., Grandy, A. Stuart, Koven, Charles D., Lombardozzi, Danica L., Oleson, Keith W., and Thomas, R. Quinn

Abstract

Land models are often used to simulate terrestrial responses to future environmental changes, but these models are not commonly evaluated with data from experimental manipulations. Results from experimental manipulations can identify and evaluate model assumptions that are consistent with appropriate ecosystem responses to future environmental change. We conducted simulations using three coupled carbon-nitrogen versions of the Community Land Model (CLM, versions 4, 4.5, and—the newly developed—5), and compared the simulated response to nitrogen (N) and atmospheric carbon dioxide (CO2) enrichment with meta-analyses of observations from similar experimental manipulations. In control simulations, successive versions of CLM showed a poleward increase in gross primary productivity and an overall bias reduction, compared to FLUXNET-MTE observations. Simulations with N and CO2 enrichment demonstrate that CLM transitioned from a model that exhibited strong nitrogen limitation of the terrestrial carbon cycle (CLM4) to a model that showed greater responsiveness to elevated concentrations of CO2 in the atmosphere (CLM5). Overall, CLM5 simulations showed better agreement with observed ecosystem responses to experimental N and CO2 enrichment than previous versions of the model. These simulations also exposed shortcomings in structural assumptions and parameterizations. Specifically, no version of CLM captures changes in plant physiology, allocation, and nutrient uptake that are likely important aspects of terrestrial ecosystems' responses to environmental change. These highlight priority areas that should be addressed in future model developments. Moving forward, incorporating results from experimental manipulations into model benchmarking tools that are used to evaluate model performance will help increase confidence in terrestrial carbon cycle projections.

Published
2019

50. Decadal fates and impacts of nitrogen additions on temperate forest carbon storage:a data-model comparison

Author

Cheng, Susan J., Hess, Peter G., Wieder, William R., Thomas, R. Quinn, Nadelhoffer, Knute J., Vira, Julius, Lombardozzi, Danica L., Gundersen, Per, Fernandez, Ivan J., Schleppi, Patrick, Gruselle, Marie-Cecile, Moldan, Filip, Goodale, Christine L., Cheng, Susan J., Hess, Peter G., Wieder, William R., Thomas, R. Quinn, Nadelhoffer, Knute J., Vira, Julius, Lombardozzi, Danica L., Gundersen, Per, Fernandez, Ivan J., Schleppi, Patrick, Gruselle, Marie-Cecile, Moldan, Filip, and Goodale, Christine L.

Published
2019

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