Your search keyword '"D. L. Woodard"' showing total 5 results

1. Hector V3.2.0: functionality and performance of a reduced-complexity climate model

Author

K. Dorheim, S. Gering, R. Gieseke, C. Hartin, L. Pressburger, A. N. Shiklomanov, S. J. Smith, C. Tebaldi, D. L. Woodard, and B. Bond-Lamberty

Subjects

Geology, QE1-996.5

Abstract

Hector is an open-source reduced-complexity climate–carbon cycle model that models critical Earth system processes on a global and annual basis. Here, we present an updated version of the model, Hector V3.2.0 (hereafter Hector V3), and document its new features, implementation of new science, and performance. Significant new features include permafrost thaw, a reworked energy balance submodel, and updated parameterizations throughout. Hector V3 results are in good general agreement with historical observations of atmospheric CO2 concentrations and global mean surface temperature, and the future temperature projections from Hector V3 are consistent with more complex Earth system model output data from the sixth phase of the Coupled Model Intercomparison Project. We show that Hector V3 is a flexible, performant, robust, and fully open-source simulator of global climate changes. We also note its limitations and discuss future areas for improvement and research with respect to the model's scientific, stakeholder, and educational priorities.

Published

2024

2. A permafrost implementation in the simple carbon–climate model Hector v.2.3pf

Author

D. L. Woodard, A. N. Shiklomanov, B. Kravitz, C. Hartin, and B. Bond-Lamberty

Subjects

Geology, QE1-996.5

Abstract

Permafrost currently stores more than a fourth of global soil carbon. A warming climate makes this carbon increasingly vulnerable to decomposition and release into the atmosphere in the form of greenhouse gases. The resulting climate feedback can be estimated using land surface models, but the high complexity and computational cost of these models make it challenging to use them for estimating uncertainty, exploring novel scenarios, and coupling with other models. We have added a representation of permafrost to the simple, open-source global carbon–climate model Hector, calibrated to be consistent with both historical data and 21st century Earth system model projections of permafrost thaw. We include permafrost as a separate land carbon pool that becomes available for decomposition into both methane (CH4) and carbon dioxide (CO2) once thawed; the thaw rate is controlled by region-specific air temperature increases from a preindustrial baseline. We found that by 2100 thawed permafrost carbon emissions increased Hector’s atmospheric CO2 concentration by 5 %–7 % and the atmospheric CH4 concentration by 7 %–12 %, depending on the future scenario, resulting in 0.2–0.25 ∘C of additional warming over the 21st century. The fraction of thawed permafrost carbon available for decomposition was the most significant parameter controlling the end-of-century temperature change in the model, explaining around 70 % of the temperature variance, and was distantly followed by the initial stock of permafrost carbon, which contributed to about 10 % of the temperature variance. The addition of permafrost in Hector provides a basis for the exploration of a suite of science questions, as Hector can be cheaply run over a wide range of parameter values to explore uncertainty and can be easily coupled with integrated assessment and other human system models to explore the economic consequences of warming from this feedback.

Published

2021

3. Reduced Complexity Model Intercomparison Project Phase 2: Synthesizing Earth System Knowledge for Probabilistic Climate Projections

Author

Z. Nicholls, M. Meinshausen, J. Lewis, M. Rojas Corradi, K. Dorheim, T. Gasser, R. Gieseke, A. P. Hope, N. J. Leach, L. A. McBride, Y. Quilcaille, J. Rogelj, R. J. Salawitch, B. H. Samset, M. Sandstad, A. Shiklomanov, R. B. Skeie, C. J. Smith, S. J. Smith, X. Su, J. Tsutsui, B. Vega‐Westhoff, and D. L. Woodard

Subjects

climate, model intercomparison, probabilistic projections, RCMIP, reduced complexity climate model, Environmental sciences, GE1-350, Ecology, QH540-549.5

Abstract

Abstract Over the last decades, climate science has evolved rapidly across multiple expert domains. Our best tools to capture state‐of‐the‐art knowledge in an internally self‐consistent modeling framework are the increasingly complex fully coupled Earth System Models (ESMs). However, computational limitations and the structural rigidity of ESMs mean that the full range of uncertainties across multiple domains are difficult to capture with ESMs alone. The tools of choice are instead more computationally efficient reduced complexity models (RCMs), which are structurally flexible and can span the response dynamics across a range of domain‐specific models and ESM experiments. Here we present Phase 2 of the Reduced Complexity Model Intercomparison Project (RCMIP Phase 2), the first comprehensive intercomparison of RCMs that are probabilistically calibrated with key benchmark ranges from specialized research communities. Unsurprisingly, but crucially, we find that models which have been constrained to reflect the key benchmarks better reflect the key benchmarks. Under the low‐emissions SSP1‐1.9 scenario, across the RCMs, median peak warming projections range from 1.3 to 1.7°C (relative to 1850–1900, using an observationally based historical warming estimate of 0.8°C between 1850–1900 and 1995–2014). Further developing methodologies to constrain these projection uncertainties seems paramount given the international community's goal to contain warming to below 1.5°C above preindustrial in the long‐term. Our findings suggest that users of RCMs should carefully evaluate their RCM, specifically its skill against key benchmarks and consider the need to include projections benchmarks either from ESM results or other assessments to reduce divergence in future projections.

Published

2021

4. ChemInform Abstract: Preparation of α-Fluorocarboxylic Acids and Derivatives

Author

S. T. Purrington and D. L. Woodard

Subjects

Chemistry, Organic chemistry, General Medicine

Published

1990

5. Reduced Complexity Model Intercomparison Project Phase 2: Synthesizing Earth System Knowledge for Probabilistic Climate Projections

Author

Ross J. Salawitch, Robert Gieseke, Thomas Gasser, Xuanming Su, Malte Meinshausen, B. A. Vega-Westhoff, L. McBride, Zebedee Nicholls, Nicholas J. Leach, Marit Sandstad, Alexey N. Shiklomanov, Joeri Rogelj, Kalyn Dorheim, D. L. Woodard, Steven J. Smith, M. Rojas Corradi, Ragnhild Bieltvedt Skeie, Christopher J. Smith, Yann Quilcaille, Jared Lewis, Junichi Tsutsui, Bjørn Hallvard Samset, and Austin P. Hope

Subjects

010504 meteorology & atmospheric sciences, 02 engineering and technology, Biogeosciences, Volcanic Effects, 01 natural sciences, 7. Clean energy, Global Change from Geodesy, Volcanic Hazards and Risks, Multidisciplinary approach, Oceans, Sea Level Change, Earth and Planetary Sciences (miscellaneous), GE1-350, Disaster Risk Analysis and Assessment, QH540-549.5, General Environmental Science, Climate and Interannual Variability, Climate Impact, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Atmospheric Processes, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, probabilistic projections, Atmospheric, Regional Modeling, Global Climate Models, Atmospheric Effects, 0207 environmental engineering, Volcanology, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, Benchmark (surveying), Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, climate, Solid Earth, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Water Cycles, Modeling, Avalanches, Volcano Seismology, RCMIP, Benefit‐cost Analysis, Earth system science, Key (cryptography), Computational Geophysics, Regional Climate Change, Natural Hazards, Abrupt/Rapid Climate Change, Informatics, Surface Waves and Tides, Atmospheric Composition and Structure, Volcano Monitoring, Projection (set theory), 020701 environmental engineering, Seismology, Climatology, Ecology, Radio Oceanography, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, reduced complexity climate model, Industrial engineering, Oceanography: General, model intercomparison, Cryosphere, Impacts of Global Change, Coupled Models of the Climate System, Oceanography: Physical, Research Article, Risk, Oceanic, Theoretical Modeling, General or Miscellaneous, Radio Science, Tsunamis and Storm Surges, Paleoceanography, Model Calibration, Climate Dynamics, Divergence (statistics), Numerical Solutions, 0105 earth and related environmental sciences, Climate Change and Variability, Effusive Volcanism, Climate Variability, Probabilistic logic, General Circulation, Policy Sciences, Climate Impacts, Mud Volcanism, Environmental sciences, Air/Sea Constituent Fluxes, Range (mathematics), Mass Balance, Ocean influence of Earth rotation, 13. Climate action, Volcano/Climate Interactions, Hydrology, Sea Level: Variations and Mean

Abstract

Over the last decades, climate science has evolved rapidly across multiple expert domains. Our best tools to capture state‐of‐the‐art knowledge in an internally self‐consistent modeling framework are the increasingly complex fully coupled Earth System Models (ESMs). However, computational limitations and the structural rigidity of ESMs mean that the full range of uncertainties across multiple domains are difficult to capture with ESMs alone. The tools of choice are instead more computationally efficient reduced complexity models (RCMs), which are structurally flexible and can span the response dynamics across a range of domain‐specific models and ESM experiments. Here we present Phase 2 of the Reduced Complexity Model Intercomparison Project (RCMIP Phase 2), the first comprehensive intercomparison of RCMs that are probabilistically calibrated with key benchmark ranges from specialized research communities. Unsurprisingly, but crucially, we find that models which have been constrained to reflect the key benchmarks better reflect the key benchmarks. Under the low‐emissions SSP1‐1.9 scenario, across the RCMs, median peak warming projections range from 1.3 to 1.7°C (relative to 1850–1900, using an observationally based historical warming estimate of 0.8°C between 1850–1900 and 1995–2014). Further developing methodologies to constrain these projection uncertainties seems paramount given the international community's goal to contain warming to below 1.5°C above preindustrial in the long‐term. Our findings suggest that users of RCMs should carefully evaluate their RCM, specifically its skill against key benchmarks and consider the need to include projections benchmarks either from ESM results or other assessments to reduce divergence in future projections., Key Points Probabilistic global‐mean temperature projections often use reduced complexity climate models (RCMs) because of their low computational costWe evaluate how well RCMs’ probabilistic setups can synthesize knowledge from multiple research domains for policy relevant projectionsNo RCM is able to capture all forcing, warming, heat uptake and carbon cycle metrics we evaluate, however some come close across a range