Divergence in Climate Model Projections of Future Arctic Atlantification

Muilwijk, Morven; Nummelin, Aleksi; Heuzé, Céline; Polyakov, Igor V.; Zanowski, Hannah; Smedsrud, Lars H.

doi:10.1175/jcli-d-22-0349.1

Cited by 30 publications

(51 citation statements)

References 55 publications

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“…Climate models are key tools for understanding future climate changes (Jahn, 2018; Landrum & Holland, 2020; Screen et al., 2018), although they are often subject to large uncertainties in the Arctic, such as for the simulated Arctic warming (Latonin et al., 2021; Pithan & Mauritsen, 2014; Smith et al., 2019), sea ice decline (Docquier et al., 2019; Li et al., 2017; Notz & Community, 2020), and Arctic Ocean hydrography and stratification (Heuzé et al., 2023; Khosravi et al., 2022; Muilwĳk et al., 2022; Shu et al., 2019). Future changes in the Arctic climate will have significant impacts on human life and marine ecosystems (Chambault et al., 2022; Ingvaldsen et al., 2021).…”

Section: Introductionmentioning

confidence: 99%

Future Arctic Climate Change in CMIP6 Strikingly Intensified by NEMO‐Family Climate Models

Pan

Shu

Wang

et al. 2023

Geophysical Research Letters

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The Arctic is very susceptible to global climate change. Its surface air temperature (SAT) is warming at a rate 2-4 times higher than the global average starting from the 1970s (Bekryaev et al., 2010;Holland & Bitz, 2003;Rantanen et al., 2022;Serreze & Barry, 2011). The phenomenon of Arctic amplification has been found not only in historical observations and climate model projection simulations, but also in proxy reconstructions of paleo climate changes (Pithan & Mauritsen, 2014;Renssen et al., 2009). Warming amplification has also been detected in the ocean component of the Arctic based on analysis of climate models (Shu et al., 2022). The sea ice decay associated with Arctic warming is a crucial indicator of both Arctic and global climate changes (Notz & Stroeve, 2016;Polyakov et al., 2010;Shu et al., 2022). Arctic sea ice extent (SIE) in September has halved since the late 1970s (Perovich et al., 2017) and the location of the winter sea ice edge has also considerably retreated, potentially affecting weather and climate across the Northern Hemisphere (

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Section: Introductionmentioning

confidence: 99%

Future Arctic Climate Change in CMIP6 Strikingly Intensified by NEMO‐Family Climate Models

Pan

Shu

Wang

et al. 2023

Geophysical Research Letters

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“…(2022), and Muilwijk et al. (2023). The connection between the Fram Strait heat transport and winter sea‐ice variability is limited in all models.…”

Section: Discussionmentioning

confidence: 97%

Expanding Influence of Atlantic and Pacific Ocean Heat Transport on Winter Sea‐Ice Variability in a Warming Arctic

Dörr,

Årthun,

Eldevik

et al. 2024

JGR Oceans

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The gradual anthropogenic‐driven retreat of Arctic sea ice is overlaid by large natural (internal) year‐to‐year variability. In winter, sea‐ice loss and variability are currently most pronounced in the Barents Sea. As the loss of winter sea ice continues in a warming world, other regions will experience increased sea‐ice variability. In this study, we investigate to what extent this increased winter sea‐ice variability in the future is connected to ocean heat transport (OHT). We analyze and contrast the present and future link between Pacific and Atlantic OHT and the winter Arctic sea‐ice cover using simulations from seven single‐model large ensembles. We find strong model agreement for a poleward expanding impact of OHT through the Bering Strait and the Barents Sea under continued sea‐ice retreat. Model differences on the Atlantic side can be explained by the differences in the simulated variance of the Atlantic inflows. Model differences on the Pacific side can be explained by differences in the simulated strength of Pacific Water inflows, and upper‐ocean stratification and vertical mixing on the Chukchi shelf. Our work highlights the increasing importance of the Pacific and Atlantic water inflows to the Arctic Ocean and highlights which factors are important to correctly simulate in order to capture the changing impact of OHT in the warming Arctic.

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“…Nevertheless, because our estimates agree to previous results for the sampled area and along the first 1,500 m, we can confirm that in 2015 the AO represented ∼2% of the global oceans' C ant inventory. As the rate of “Atlantification” of the Eurasian Basin is expected to increase in the future (Muilwijk et al., 2023), and since the Atlantic‐origin waters are the main source of C ant to this region, the magnitude and distribution of such inventory is also likely to change. Therefore, this work highlights the potential of Atlantic‐derived tracers such as 129 I and 236 U (among others released from nuclear reprocessing plants), to target future changes in C ant in the Arctic Ocean.…”

Section: Discussionmentioning

confidence: 99%

Anthropogenic Carbon in the Arctic Ocean: Perspectives From Different Transient Tracers

Raimondi,

Wefing,

Casacuberta

2023

JGR Oceans

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In this study we investigated the physical characteristics of the Atlantic layer in the Arctic Ocean (AO) and its role in the distribution and storage of anthropogenic carbon (Cant). The novelty of this work is to use the Transit Time Distribution method (TTD) with the radionuclides 129I and 236U and its comparison to the commonly applied gas tracers, CFC‐12 and SF6. Overall, our examination of two distinct tracer pairs, along with the novel TTD method in comparison to a classical approach, revealed a notable agreement, highlighting the robustness of these Cant estimates. The TTD analysis based on radionuclides showed that whereas the Eurasian Basin has shorter transit times and is dominated by strong mixing conditions, the Amerasian Basin is characterized by longer transit times and a strong advective flow. Overall, the Cant concentrations obtained from radionuclides confirm that the distribution in the AO follows its circulation patterns, with higher concentrations in the Eurasian Basin (∼50 μmol kg−1) compared to the Amerasian one (∼36–42 μmol kg−1). An estimated partial inventory of 0.85 ± 0.17 and 1.0 ± 0.03 Pg C was assessed for 2015 from the novel application of TTD with radionuclides and gas tracers, respectively. Finally, we identified the saturation of gas tracers as a larger source of uncertainty for Cant estimation compared to the uncertainty associated to different radionuclides' input functions, thus remarking the importance of including non‐saturation dependent tracers, such as radionuclides, as an additional tool to support Cant estimates in the AO.

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Divergence in Climate Model Projections of Future Arctic Atlantification

Cited by 30 publications

References 55 publications

Future Arctic Climate Change in CMIP6 Strikingly Intensified by NEMO‐Family Climate Models

Future Arctic Climate Change in CMIP6 Strikingly Intensified by NEMO‐Family Climate Models

Expanding Influence of Atlantic and Pacific Ocean Heat Transport on Winter Sea‐Ice Variability in a Warming Arctic

Anthropogenic Carbon in the Arctic Ocean: Perspectives From Different Transient Tracers

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