A Bayesian framework for emergent constraints: case studies of climate sensitivity with PMIP

Renoult, Martin; Hargreaves, J. C.; Sagoo, Navjit; Flynn, Clare M.; Kapsch, Marie‐Luise; Li, Qiang; Lohmann, Gerrit; Mikolajewicz, Uwe; Ohgaito, Rumi; Shi, Xiaoxu; Zhang, Qiong; Mauritsen, Thorsten

doi:10.5194/cp-16-1715-2020

Cited by 24 publications

(37 citation statements)

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“…The temperature anomaly of LGM relative to PI over the tropics is negative and there is general quantitative agreement between the anomaly derived from the model and that from proxy data (Bartlein et al, 2011;MARGO project members et al, 2009). This could be useful in constraining future projections, given that Annan and Hargreaves (2006) and Renoult et al (2020) revealed the correlation between tropical cooling at LGM and ECS. It has been pointed out in Stocker et al (2013) Fifth Assessment Report that the cooling over Greenland during the LGM relative to PI is underestimated in the models.…”

Section: Outlook and Conclusionmentioning

confidence: 53%

“…As LGM cooling relative to the pre-industrial (PI) experiment over the tropics is at a comparable level to equilibrium climate sensitivity (ECS), LGM modeling can provide useful information to constrain climate sensitivity for projections of future climate (Annan and Hargreaves, 2006;Renoult et al, 2020). Intercomparison studies of proxy-based reconstructions of climate variables and model output continue to be conducted (Braconnot et al, 2007;Bartlein et al, 2011;Kageyama et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

“…The interglacial periods of 6000 and 127 000 years before present were characterized by differences in solar radiation at the top of the atmosphere caused by orbital states that were different from those of the present day (Brierley et al, 2020;Otto-Bliesner et al, 2021), resulting in seasonalities that were different from the PI period (1850 CE). As it was in the recent past and because various paleo-proxy records are available (Ritchie et al, 1985;Drake et al, 2011;Hely et al, 2014;Tierney et al, 2013Tierney et al, , 2017, the interglacial period of 6000 years before present was the only interglacial included in earlier phases of PMIP (Braconnot et al, 2007;Abe-Ouchi, 2007, 2009;Ohgaito et al, 2013). Following efforts to collect paleo-proxy data (Otto-Bliesner and Brady, 2001;Lunt et al, 2013;Capron et al, 2014Capron et al, , 2017, it is now also possible to conduct the same experiment for 127 000 years before present; experiments on this interglacial period have the advantage of strong seasonality in the Northern Hemisphere (NH).…”

Section: Introductionmentioning

confidence: 99%

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PMIP4 experiments using MIROC-ES2L Earth system model

et al. 2021

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Abstract. Following the protocol of the fourth phase of the Paleoclimate Modelling Intercomparison Project (PMIP4), we performed numerical experiments targeting distinctive past time periods using the Model for Interdisciplinary Research on Climate, Earth System version 2 for Long-term simulations (MIROC-ES2L), which is an Earth system model. Setup and basic performance of the experiments are presented. The Last Glacial Maximum was one of the most extreme climate states during the Quaternary and conducting numerical modeling experiments of this period has long been a challenge for the paleoclimate community. We conducted a Last Glacial Maximum experiment with a long spin-up of nearly 9000 years. Globally, there was reasonable agreement between the anomalies relative to the present day derived from model climatology and those derived from proxy data archives, while some regional discrepancies remained. By changing orbital and greenhouse gas forcings, we conducted experiments for two interglacial periods: 6000 and 127 000 years before present. Model anomalies relative to the present day were qualitatively consistent with variations in solar forcing. However, anomalies in the model were smaller than those derived from proxy data archives, suggesting that processes that play a role in past interglacial climates remain lacking in this state-of-the-art model. We conducted transient simulations from 850 to 1850 CE and from 1850 to 2014 CE. Cooling in the model indicated a clear response to huge volcanic eruptions, consistent with paleo-proxy data. The contrast between cooling during the Little Ice Age and warming during the 20th to 21st centuries was represented well at the multidecadal timescale.

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Section: Outlook and Conclusionmentioning

confidence: 53%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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PMIP4 experiments using MIROC-ES2L Earth system model

et al. 2021

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“…For all emergent constraints, we use the historical simulations of CMIP5 and CMIP6 in order to ensure maximum agreement with the observational data. If necessary, the historical simulation of CMIP5 is extended after its final year 2005 with data from the RCP8.5 scenario (Riahi et al, 2011). Note that we only use data through 2014, during which time all RCP scenarios behave similarly and the choice of the scenario is not expected to affect results considerably.…”

Section: Calculation Of Emergent Constraints On Ecsmentioning

confidence: 99%

“…Similar to many other emergent constraint studies, we use an ordinary least-squares linear regression model for each emergent constraint. However, in some cases this might not be appropriate, e.g., when we expect nonlinear behavior or when physical constraints can be used to derive further constraints for the regression model like a zero intercept (Annan et al, 2020; Jimenez-de-la-Cuesta and Renoult et al, 2020).…”

Section: Calculation Of Emergent Constraints On Ecsmentioning

confidence: 99%

Emergent constraints on equilibrium climate sensitivity in CMIP5: do they hold for CMIP6?

et al. 2020

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Abstract. An important metric for temperature projections is the equilibrium climate sensitivity (ECS), which is defined as the global mean surface air temperature change caused by a doubling of the atmospheric CO2 concentration. The range for ECS assessed by the Intergovernmental Panel on Climate Change (IPCC) Fifth Assessment Report is between 1.5 and 4.5 K and has not decreased over the last decades. Among other methods, emergent constraints are potentially promising approaches to reduce the range of ECS by combining observations and output from Earth System Models (ESMs). In this study, we systematically analyze 11 published emergent constraints on ECS that have mostly been derived from models participating in the Coupled Model Intercomparison Project Phase 5 (CMIP5) project. These emergent constraints are – except for one that is based on temperature variability – all directly or indirectly based on cloud processes, which are the major source of spread in ECS among current models. The focus of the study is on testing if these emergent constraints hold for ESMs participating in the new Phase 6 (CMIP6). Since none of the emergent constraints considered here have been derived using the CMIP6 ensemble, CMIP6 can be used for cross-checking of the emergent constraints on a new model ensemble. The application of the emergent constraints to CMIP6 data shows a decrease in skill and statistical significance of the emergent relationship for nearly all constraints, with this decrease being large in many cases. Consequently, the size of the constrained ECS ranges (66 % confidence intervals) widens by 51 % on average in CMIP6 compared to CMIP5. This is likely because of changes in the representation of cloud processes from CMIP5 to CMIP6, but may in some cases also be due to spurious statistical relationships or a too small number of models in the ensemble that the emergent constraint was originally derived from. The emergently- constrained best estimates of ECS also increased from CMIP5 to CMIP6 by 12 % on average. This can be at least partly explained by the increased number of high-ECS (above 4.5 K) models in CMIP6 without a corresponding change in the constraint predictors, suggesting the emergence of new feedback processes rather than changes in strength of those previously dominant. Our results support previous studies concluding that emergent constraints should be based on an independently verifiable physical mechanism, and that process-based emergent constraints on ECS should rather be thought of as constraints for the process or feedback they are actually targeting.

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Simulating Miocene Warmth: Insights From an Opportunistic Multi‐Model Ensemble (MioMIP1)

Burls

Bradshaw

Boer

et al. 2021

Paleoceanog and Paleoclimatol

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The Miocene epoch, spanning 23.03-5.33 Ma, was a dynamic climate of sustained, polar amplified warmth. Miocene atmospheric CO 2 concentrations are typically reconstructed between 300 and 600 ppm and were potentially higher during the Miocene Climatic Optimum (16.75-14.5 Ma). With surface temperature reconstructions pointing to substantial midlatitude and polar warmth, it is unclear what processes maintained the much weaker-than-modern equator-to-pole temperature difference. Here, we synthesize several Miocene climate modeling efforts together with available terrestrial and ocean surface temperature reconstructions. We evaluate the range of model-data agreement, highlight robust mechanisms operating across Miocene modeling efforts and regions where differences across experiments result in a large spread in warming responses. Prescribed CO 2 is the primary factor controlling global warming across the ensemble. On average, elements other than CO 2 , such as Miocene paleogeography and ice sheets, raise global mean temperature by ∼2°C, with the spread in warming under a given CO 2 concentration (due to a combination of the spread in imposed boundary conditions and climate feedback strengths) equivalent to ∼1.2 times a CO 2 doubling. This study uses an ensemble of opportunity: models, boundary conditions, and reference data sets represent the state-of-art for the Miocene, but are inhomogeneous and not ideal for a formal intermodel comparison effort. Acknowledging this caveat, this study is nevertheless the first Miocene multi-model, multi-proxy comparison attempted so far. This study serves to take stock of the current progress toward simulating Miocene warmth while isolating remaining challenges that may be well served by community-led efforts to coordinate modeling and data activities within a common analytical framework.Plain Language Summary As human activity continues to increase atmospheric carbon dioxide concentrations, scientists turn to warm intervals in Earth's history to develop insight into the behavior of the climate system under elevated carbon dioxide and temperature. One such interval is the Miocene epoch which has become increasingly relevant as reconstructions of Miocene atmospheric CO 2 concentrations point to values ranging between current concentrations of ∼400 ppm and those projected for the end of this century under Shared Socioeconomic Pathways 3 and 4. In this study, we evaluate the BURLS ET AL.

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A Bayesian framework for emergent constraints: case studies of climate sensitivity with PMIP

Cited by 24 publications

References 58 publications

PMIP4 experiments using MIROC-ES2L Earth system model

PMIP4 experiments using MIROC-ES2L Earth system model

Emergent constraints on equilibrium climate sensitivity in CMIP5: do they hold for CMIP6?

Simulating Miocene Warmth: Insights From an Opportunistic Multi‐Model Ensemble (MioMIP1)

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