Late Cretaceous climate simulations with different CO<sub>2</sub> levels and subarctic gateway configurations: A model‐data comparison

Niezgodzki, Igor; Knorr, Gregor; Lohmann, Gerrit; Tyszka, Jarosław; Markwick, Paul J.

doi:10.1002/2016pa003055

Cited by 36 publications

(20 citation statements)

References 149 publications

(262 reference statements)

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“…21d) This simulation, and by extant the overall response of IPSL-CM5A2 to a Cretaceous paleogeography without ice sheets and elevated CO2 levels, would need to be evaluated in more details against previous work and proxy data. Still, the basic analysis presented here demonstrates that the mean climate simulated by our model shares many similarities with that simulated by other investigations of Cretaceous warmth with coupled models (Niezgodzki et al, 2017;Tabor et al, 2016;Upchurch et al, 2015). It therefore suggests that our goal of adapting the IPSL ESM to deep-time boundary conditions has been reached with success.…”

Section: Mean Surface Climatesupporting

confidence: 70%

IPSL-CM5A2. An Earth System Model designed for multi-millennial climate simulations

Sepulchre¹,

Caubel²,

Ladant³

et al. 2019

Preprint

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Abstract. Based on the CMIP5-generation previous IPSL earth system model, we designed a new version, IPSL-CM5A2, aiming at running multi-millennial simulations typical of deep-time paleoclimates studies. Three priorities were followed during the set-up of the model: (1) improving the overall model computing performance, (2) overcoming a persistent cold bias depicted in the previous model generation, and (3) making the model able to handle the specific continental configurations of the geological past. Technical developments have been performed on separate components and on the coupling system to speed up the whole coupled model. These developments include the integration of hybrid parallelization MPI-OpenMP in LMDz atmospheric component, the use of a new library to perform parallel asynchronous input/output by using computing cores as “IO servers”, the use of a parallel coupling library between the ocean and the atmospheric components. The model can now simulate ~100 years per day, opening new possibilities towards the production of multi-millennial simulations with a full earth system model. The tuning strategy employed to overcome a persistent cold bias is detailed. The confrontation of an historical simulation to climatological observations shows overall improved ocean meridional overturning circulation, marine productivity and latitudinal position of zonal wind patterns. We also present the numerous steps required to run the IPSL-CM5A2 for deep-time paleoclimates through a preliminary case-study for the Cretaceous. Namely, a specific work on the ocean model grid was required to run the model for specific continental configurations in which continents are relocated according to past paleogeographic reconstructions. By briefly discussing the spin-up of such a simulation, we elaborate on the requirements and challenges awaiting paleoclimate modelling in the next years, namely finding the best trade-off between the level of description of the processes and the computing cost on supercomputers.

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Section: Mean Surface Climatesupporting

confidence: 70%

IPSL-CM5A2. An Earth System Model designed for multi-millennial climate simulations

Sepulchre¹,

Caubel²,

Ladant³

et al. 2019

Preprint

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“…Indeed, the water denser than 27.8 kg m −3 flowing southward reaches 1.5 Sv in IPSL-CM5A2, while it was only 0.2 Sv in IPSL-CM5A. It remains largely underestimated as the observations from Olsen et al (2008) indicate around 6 Sv of overflow in total from observation-based estimates over the last few decades. Besides, the poleward shift of the westerlies in the North Atlantic stimulate a northward shift of the boundary between the Atlantic subtropical and subpolar gyres, as shown by the barotropic streamfunction anomaly (Fig.…”

Section: Ocean Heat Transport and Meridional Overturning Circulationmentioning

confidence: 97%

IPSL-CM5A2 – an Earth system model designed for multi-millennial climate simulations

et al. 2020

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Abstract. Based on the fifth phase of the Coupled Model Intercomparison Project (CMIP5)-generation previous Institut Pierre Simon Laplace (IPSL) Earth system model, we designed a new version, IPSL-CM5A2, aiming at running multi-millennial simulations typical of deep-time paleoclimate studies. Three priorities were followed during the setup of the model: (1) improving the overall model computing performance, (2) overcoming a persistent cold bias depicted in the previous model generation and (3) making the model able to handle the specific continental configurations of the geological past. These developments include the integration of hybrid parallelization Message Passing Interface – Open Multi-Processing (MPI-OpenMP) in the atmospheric model of the Laboratoire de Météorologie Dynamique (LMDZ), the use of a new library to perform parallel asynchronous input/output by using computing cores as “I/O servers” and the use of a parallel coupling library between the ocean and the atmospheric components. The model, which runs with an atmospheric resolution of 3.75∘×1.875∘ and 2 to 0.5∘ in the ocean, can now simulate ∼100 years per day, opening new possibilities towards the production of multi-millennial simulations with a full Earth system model. The tuning strategy employed to overcome a persistent cold bias is detailed. The confrontation of a historical simulation to climatological observations shows overall improved ocean meridional overturning circulation, marine productivity and latitudinal position of zonal wind patterns. We also present the numerous steps required to run IPSL-CM5A2 for deep-time paleoclimates through a preliminary case study for the Cretaceous. Namely, specific work on the ocean model grid was required to run the model for specific continental configurations in which continents are relocated according to past paleogeographic reconstructions. By briefly discussing the spin-up of such a simulation, we elaborate on the requirements and challenges awaiting paleoclimate modeling in the next years, namely finding the best trade-off between the level of description of the processes and the computing cost on supercomputers.

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“…The simulated SST latitudinal gradients range from 0.32°C/°latitude to 0.55°C/°latitude (Lunt et al, 2012;Tabor et al, 2016;Zhu et al, 2019;Fig. 11) and the atmospheric latitudinal gradients from 0.33°C/°latitude to 0.78°C/°latitude (Huber and Caballero, 2011;Lunt et al, 2012;Niezgodzki et al, 2017;Upchurch et al, 2015;Zhu et al, 2019; See Fig. 11), with the lowest latitudinal gradients being obtained for the highest pCO2 values.…”

Section: Discussion 41 About the Cenomanian-turonian Climatementioning

confidence: 99%

“…The signal includes 9°C due to the fourfold increase of pCO2 or a 4.5°C increase for a doubling of pCO2 (assuming that the response is linear), which agrees with the high end of the investigations mentioned above. Whilst large, latest generation of earth system models also show an increasingly higher climate sensitivity to increased CO2 (Golaz et al, 2019;Hutchinson et al, 2018;Niezgodzki et al, 2017), suggesting that the sensitivity could have been underestimated in earlier studies. For example, the recent study of Zhu (2019), using an up-to-date parametrization of cloud microphysics in the CESM1.2 model, proposes an Eocene Climate Sensitivity of 6.6°C for a doubling of CO2 from 3 to 6 PAL.…”

Section: Cretaceous Climate Controlling Factorsmentioning

confidence: 99%

Stripping back the Modern to reveal Cretaceous climate and temperature gradient underneath

Laugié

Donnadieu

Ladant

et al. 2020

Preprint

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Abstract. During past geological times, the Earth suffered several intervals of global warmth but their driving factors remain equivocal. A careful appraisal of the main processes involved in those past events is essential to evaluate how they can inform future climates, and thus to provide decision makers with a clear understanding of the processes at play in a warmer world. In this context, the greenhouse Earth of the Cretaceous era, specifically the Cenomanian-Turonian (~ 94 Ma), is of particular interest, as it corresponds to a thermal maximum. Here we use the IPSL-CM5A2 Earth System Model to unravel the forcing parameters of the Cenomanian-Turonian greenhouse climate. We perform six simulations with an incremental change in five major boundary conditions in order to isolate their respective role on climate change between the Cretaceous and the preindustrial. Starting with a preindustrial simulation, we implement: (1) the absence of polar ice sheets, (2) the increase in atmospheric pCO2 to 1120 ppm, (3) the change of vegetation and soil parameters, (4) the 1 % decrease in the Cenomanian-Turonian value of the solar constant and (5) the Cenomanian-Turonian paleogeography. Between the first (preindustrial) simulation and the last (Cretaceous) simulation, the model simulates a global warming of more than 11 °C. Most of this warming is driven by the increase in atmospheric pCO2 to 1120 ppm. Paleogeographic changes represent the second major contributor to the global warming while the reduction in the solar constant counteracts most of the geographically-driven global warming. We also demonstrate that the implementation of Cretaceous boundary conditions flattens the temperature gradients compared to the piControl simulation. Interestingly, we show that paleogeography is the major driver of the flattening in the low- to mid-latitudes whereas the pCO2 rise and polar ice sheet retreat dominate the high-latitudes response.

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Late Cretaceous climate simulations with different CO₂ levels and subarctic gateway configurations: A model‐data comparison

Cited by 36 publications

References 149 publications

IPSL-CM5A2. An Earth System Model designed for multi-millennial climate simulations

IPSL-CM5A2. An Earth System Model designed for multi-millennial climate simulations

IPSL-CM5A2 – an Earth system model designed for multi-millennial climate simulations

Stripping back the Modern to reveal Cretaceous climate and temperature gradient underneath

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Late Cretaceous climate simulations with different CO2 levels and subarctic gateway configurations: A model‐data comparison

Cited by 36 publications

References 149 publications

IPSL-CM5A2. An Earth System Model designed for multi-millennial climate simulations

IPSL-CM5A2. An Earth System Model designed for multi-millennial climate simulations

IPSL-CM5A2 – an Earth system model designed for multi-millennial climate simulations

Stripping back the Modern to reveal Cretaceous climate and temperature gradient underneath

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Product

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Late Cretaceous climate simulations with different CO₂ levels and subarctic gateway configurations: A model‐data comparison