What causes the spread of model projections of ocean dynamic sea-level change in response to greenhouse gas forcing?

Couldrey, Matthew; Gregory, Jonathan M.; Dias, Fabio Boeira; Dobrohotoff, Peter; Domingues, Catia M.; Garuba, O. A.; Griffies, Stephen M.; Haak, Helmuth; Hu, Aixue; Ishii, M.; Jungclaus, Johann; Köhl, Armin; Marsland, Simon J.; Ojha, Sayantani; Saenko, Oleg A.; Savita, Abhishek; Shao, Andrew; Stammer, Detlef; Suzuki, Tatsuo; Todd, Alexander D.; Zanna, Laure

doi:10.1007/s00382-020-05471-4

Cited by 36 publications

(50 citation statements)

References 85 publications

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“…All surface forcing perturbations are applied at the ocean surface, such that sea ice is not directly affected (Fig. 1, see also Couldrey et al 2021). However, there will be indirect effects on sea ice due to the changes of heat and freshwater in response to all the perturbations.…”

Section: Methodsmentioning

confidence: 99%

“…Gregory et al (2016) provide more details on FAFMIP and first results in terms of ensemble mean and spread of the total resulting sea level anomalies and the comparison to those resulting from individual forcing using low-resolution models. More recently, Couldrey et al (2021)showed that surface heat flux changes drive most of the sea level change pattern in the FAFMIP runs and that the spread between underlying Atmosphere-Ocean General Circulation Models (AOGCM) is caused largely by differences in their regional transport adjustment, which redistributes regional heat content differences that existed in the ocean prior to perturbation. However, the quantification of the mechanisms behind the simulated responses as a function of surface forcing agent remains unclear in previous publications.…”

Section: Introductionmentioning

confidence: 99%

“…Novel aspects of this study include (i) the analysis of an additional passive salt experiment (see Sect. 2.2), (ii) the quantification of the impact of feedbacks between individual forcing components on the solution and (iii) focusing on the highest resolution model in the ensemble previously analyzed by Couldrey et al (2021).…”

Section: Introductionmentioning

confidence: 99%

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Sea level changes mechanisms in the MPI-ESM under FAFMIP forcing conditions

et al. 2022

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Mechanistic causes for sea level (SL) change patterns are analyzed as they emerge from the Coupled Model Intercomparison Project Phase 6 (CMIP6) endorsed Flux-Anomaly-Forced Model Intercomparison Project (FAFMIP) coupled climate experiments imposing individual forcing anomalies in wind stress, heatflux and freshwater flux to the Max-Planck-Institute Earth System Model (MPI-ESM). It appears that the heat flux perturbations have the largest effect on the sea level. In contrast, the direct impact of momentum and freshwater flux anomalies on SL anomalies appear to be limited to some region e.g. the Southern Ocean, Arctic Ocean and to some extent the North Pacific and North Atlantic Ocean. We find that thermosteric changes dominate the total SL change over large parts of the global ocean, except north of 60 °N where halosteric changes prevail. An analysis of added and redistributed components of heat and freshwater further suggests that the added component dominates the thermosteric SL and the redistributed component dominates the halosteric SL. Due to feedback processes a superposition of all forcing components together leads to the simulated sea level changes in each individual experiment. As a result, large surface heat flux anomalies over the Atlantic lead to wind stress change outside of the Atlantic through teleconnections, which in turn appear to be the primary driving agent for changes of sea level outside of the Atlantic in all three experiments. The associated wind driven Sverdrup stream function implicates that outside of the Atlantic most of the feedback can be explained by changes in the Sverdrup circulation.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Sea level changes mechanisms in the MPI-ESM under FAFMIP forcing conditions

et al. 2022

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“…DOI 10.1175/JCLI-D-20-0603.1. Unauthenticated | Downloaded 12/13/21 02:57 AM UTC  Finally, the relevance of improving estimation of OHCA and providing full quantification of uncertainty is justified by the uses in a wide range of climate science, such as hindcast reanalyses assimilating ocean data (Storto et al 2019), ocean and/or climate model analyses investigating the mechanisms of ocean heat uptake (Couldrey et al 2020;Dias et al 2020a;Dias et al 2020b;Gregory 2000;Gregory et al 2016;Saenko et al 2021;Savita et al 2021), detection and attribution of changes to natural and anthropogenic drivers (e.g. Gleckler et al 2012), and in constraining model projections of climate and sea level change relevant for policyand decision-makers (Lyu et al 2021;Mimura 2007;Oppenheimer et al 2019).…”

Section: Conclusion and Recommendationsmentioning

confidence: 99%

Quantifying Spread in Spatiotemporal Changes of Upper-Ocean Heat Content Estimates: An Internationally Coordinated Comparison

et al. 2022

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The Earth system is accumulating energy due to human-induced activities. More than 90% of this energy has been stored in the ocean as heat since 1970, with ~64% of that in the upper 700 m. Differences in upper ocean heat content anomaly (OHCA) estimates, however, exist. Here, we use a dataset protocol for 1970–2008 – with six instrumental bias adjustments applied to expendable bathythermograph (XBT) data, and mapped by six research groups – to evaluate the spatio-temporal spread in upper OHCA estimates arising from two choices: firstly, those arising from instrumental bias adjustments; and secondly those arising from mathematical (i.e. mapping) techniques to interpolate and extrapolate data in space and time. We also examined the effect of a common ocean mask, which reveals that exclusion of shallow seas can reduce global OHCA estimates up to 13%. Spread due to mapping method is largest in the Indian Ocean and in the eddy-rich and frontal regions of all basins. Spread due to XBT bias adjustment is largest in the Pacific Ocean within 30°N–30°S. In both mapping and XBT cases, spread is higher for 1990–2004. Statistically different trends among mapping methods are not only found in the poorly-observed Southern Ocean but also on the well-observed Northwest Atlantic. Our results cannot determine the best mapping or bias adjustment schemes but they identify where important sensitivities exist, and thus where further understanding will help to refine OHCA estimates. These results highlight the need for further coordinated OHCA studies to evaluate the performance of existing mapping methods along with comprehensive assessment of uncertainty estimates.

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“…To produce the regional SLR of the sterodynamic contribution, we use the spatial patterns of ocean dynamic sea-level changes of the IPCC AR5 models. This relies on the assumption that the regional variability of sea-level sterodynamic projections is driven by the same mechanisms in Kopp et al (2014) and for the IPCC AR5, as suggested by Couldrey et al (2021).…”

Section: Sterodynamic Componentmentioning

confidence: 99%

High-End Scenarios of Sea-Level Rise for Coastal Risk-Averse Stakeholders

et al. 2021

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Sea-level rise (SLR) will be one of the major climate change-induced risks of the 21st century for coastal areas. The large uncertainties of ice sheet melting processes bring in a range of unlikely – but not impossible – high-end sea-level scenarios (HESs). Here, we provide global to regional HESs exploring the tails of the distribution estimates of the different components of sea level. We base our scenarios on high-end physical-based model projections for glaciers, ocean sterodynamic effects, glacial isostatic adjustment and contributions from land-water, and we rely on a recent expert elicitation assessment for Greenland and Antarctic ice-sheets. We consider two future emissions scenarios and three time horizons that are critical for risk-averse stakeholders (2050, 2100, and 2200). We present our results from global to regional scales and highlight HESs spatial divergence and their departure from global HESs through twelve coastal city and island examples. For HESs-A, the global mean-sea level (GMSL) is projected to reach 1.06(1.91) in the low(high) emission scenario by 2100. For HESs-B, GMSL may be higher than 1.69(3.22) m by 2100. As far as 2050, while in most regions SLR may be of the same order of magnitude as GMSL, at local scale where ice-sheets existed during the Last Glacial Maximum, SLR can be far lower than GMSL, as in the Gulf of Finland. Beyond 2050, as sea-level continue to rise under the HESs, in most regions increasing rates of minimum(maximum) HESs are projected at high(low-to-mid) latitudes, close to (far from) ice-sheets, resulting in regional HESs substantially lower(higher) than GMSL. In regions where HESs may be extremely high, some cities in South East Asia such as Manila are even more immediately affected by coastal subsidence, which causes relative sea-level changes that exceed our HESs by one order of magnitude in some sectors.

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What causes the spread of model projections of ocean dynamic sea-level change in response to greenhouse gas forcing?

Cited by 36 publications

References 85 publications

Sea level changes mechanisms in the MPI-ESM under FAFMIP forcing conditions

Sea level changes mechanisms in the MPI-ESM under FAFMIP forcing conditions

Quantifying Spread in Spatiotemporal Changes of Upper-Ocean Heat Content Estimates: An Internationally Coordinated Comparison

High-End Scenarios of Sea-Level Rise for Coastal Risk-Averse Stakeholders

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