The Atlantic Meridional Overturning Circulation in High‐Resolution Models

Hirschi, Joël; Barnier, Bernard; Böning, Claus W.; Biastoch, Arne; Blaker, Adam T.; Coward, Andrew C.; Danilov, Sergey; Drijfhout, Sybren; Getzlaff, Klaus; Griffies, Stephen M.; Hasumi, Hiroyasu; Hewitt, Helene T.; Iovino, Doroteaciro; Kawasaki, Takao; Kiss, Andrew E.; Koldunov, Nikolay; Marzocchi, Alice; Mecking, Jennifer; Moat, Ben; Molines, Jean‐Marc; Myers, Paul G.; Penduff, Thierry; Roberts, Malcolm; Tréguier, Anne‐Marie; Sein, Dmitry V.; Sidorenko, Dmitry; Small, R. Justin; Spence, Paul; Thompson, LuAnne; Weijer, Wilbert; Xu, Xiaobiao

doi:10.1029/2019jc015522

Cited by 89 publications

(112 citation statements)

References 281 publications

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“…3, left). Similar results are found in Hirschi et al (2020). However the GIN seas overturning is weaker in MR in both coordinates.…”

Section: Amoc Mean State and Responsesupporting

confidence: 86%

“…The higher resolution models mostly (with one exception, EC-EARTH-HR) have a more westerly location of the North Atlantic current at 50 • N. The high resolution models also have a stronger subpolar gyre strength (Fig. 11c), consistent with a multi-model study of ocean only models (Hirschi et al 2020). These circulation differences are likely to be responsible for a greater transport of North Atlantic water Fig.…”

Section: Influence Of the Mean Statesupporting

confidence: 75%

“…One factor thought to affect the AMOC strength is the horizontal resolution in the ocean. Many studies have found a stronger AMOC in higher resolution models (Roberts et al 2016(Roberts et al , 2019aSein et al 2018;Menary et al 2018;Docquier et al 2019;Hirschi et al 2020), though other studies have found a weaker AMOC in higher resolution models (Yokohata et al 2007;Delworth et al 2012;Winton et al 2014). Increasing resolution from non-eddying to eddy-permitting (or even eddy-resolving) has been shown to improve biases in the North Atlantic (Small et al 2014;Menary et al 2018;Roberts et al 2018Roberts et al , 2019aCaldwell et al 2019).…”

Section: Introductionmentioning

confidence: 99%

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Impact of ocean resolution and mean state on the rate of AMOC weakening

et al. 2020

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We examine the weakening of the Atlantic Meridional Overturning Circulation (AMOC) in response to increasing CO 2 at different horizontal resolutions in a state-of-the-art climate model and in a small ensemble of models with differing resolutions. There is a strong influence of the ocean mean state on the AMOC weakening: models with a more saline western subpolar gyre have a greater formation of deep water there. This makes the AMOC more susceptible to weakening from an increase in CO 2 since weakening ocean heat transports weaken the contrast between ocean and atmospheric temperatures and hence weaken the buoyancy loss. In models with a greater proportion of deep water formation further north (in the Greenland-Iceland-Norwegian basin), deep-water formation can be maintained by shifting further north to where there is a greater ocean-atmosphere temperature contrast. We show that ocean horizontal resolution can have an impact on the mean state, and hence AMOC weakening. In the models examined, those with higher resolutions tend to have a more westerly location of the North Atlantic Current and stronger subpolar gyre. This likely leads to a greater impact of the warm, saline subtropical Atlantic waters on the western subpolar gyre resulting in greater dense water formation there. Although there is some improvement of the higher resolution models over the lower resolution models in terms of the mean state, both still have biases and it is not clear which biases are the most important for influencing the AMOC strength and response to increasing CO 2 .

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“…3, left). Similar results are found in Hirschi et al (2020). However the GIN seas overturning is weaker in MR in both coordinates.…”

Section: Amoc Mean State and Responsesupporting

confidence: 86%

Section: Influence Of the Mean Statesupporting

confidence: 75%

Section: Introductionmentioning

confidence: 99%

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Impact of ocean resolution and mean state on the rate of AMOC weakening

et al. 2020

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“…This is due to the large seasonal variability of the AMOC, associated with the migration of the Intertropical Convergence Zone (ITCZ) and the changes in wind patterns and Ekman transport (Xu et al, 2014). The standard deviations based on annual means does not show such a maximum near the Equator (see Figure 7 in Hirschi et al 2019 for results based on different averaging scales). The variability is much weaker beyond the equatorial region.…”

Section: Zonal Amoc Mean and Variancementioning

confidence: 99%

Impact of horizontal resolution on global ocean-sea-ice model simulations based on the experimental protocols of the Ocean Model Intercomparison Project phase 2 (OMIP-2)

Chassignet¹,

Yeager²,

Fox‐Kemper³

et al. 2020

Preprint

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Abstract. This paper presents global comparisons of fundamental global climate variables from a suite of four pairs of matched low- and high-resolution ocean and sea-ice simulations that are obtained following the OMIP-2 protocol (Griffies et al., 2016) and integrated for one cycle (1958–2018) of the JRA55-do atmospheric state and runoff dataset (Tsujino et al., 2018). Our goal is to assess the robustness of climate-relevant improvements in ocean simulations (mean and variability) associated with moving from coarse (~ 1º) to eddy-resolving (~ 0.1º) horizontal resolutions. The models are diverse in their numerics and parameterizations, but each low-resolution and high-resolution pair of models is matched so as to isolate, to the extent possible, the effects of horizontal resolution. A variety of observational datasets are used to assess the fidelity of simulated temperature and salinity, sea surface height, kinetic energy, heat and volume transports, and sea ice distribution. This paper provides a crucial benchmark for future studies comparing and improving different schemes in any of the models used in this study or similar ones. The biases in the low-resolution simulations are familiar and their gross features – position, strength, and variability of western boundary currents, equatorial currents, and Antarctic Circumpolar Current – are significantly improved in the high-resolution models. However, despite the fact that the high-resolution models "resolve" most of these features, the improvements in temperature or salinity are inconsistent among the different model families and some regions show increased bias over their low-resolution counterparts. Greatly enhanced horizontal resolution does not deliver unambiguous bias improvement in all regions for all models.

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“…During recent decades, satellite and in situ observations with high spatial resolution (1-10 km) and high temporal resolution (days to weeks) have made a significant contribution to a better understanding of the importance of mesoscale eddies in the large-scale ocean dynamics (Golivets & Koshlyakov, 2003;Lozier, 2010;Maze et al, 1997;Wunsch & Ferrari, 2004). Most frequently developed as a result of dynamic instability of the mean flows, eddies play a major role in the cross-frontal exchange (Dutkiewicz et al, 2001;Fratantoni, 2001;Spall & Chapman, 1998) and influence the along-front advection intensity (Danabasoglu et al, 1994;Hirschi et al, 2020;Luo & Lu, 2000). Having horizontal dimensions from tens to hundreds of kilometers and vertical scales of hundreds of meters (Chelton et al, 2011;Jacobs et al, 2001;Kamenkovich et al, 2012;Shoosmith et al, 2005), a single eddy may carry trillions of tons of water and dozens of terajoules of heat (Bashmachnikov et al, 2015;Jayne & Marotzke, 2002;Wunsch, 1999).…”

Section: Introductionmentioning

confidence: 99%

Eddies in the North Greenland Sea and Fram Strait From Satellite Altimetry, SAR and High‐Resolution Model Data

et al. 2020

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In this study, we investigate eddy dynamics in the northern Greenland Sea and the Fram Strait using AVISO altimetry, spaceborne synthetic aperture radar (SAR), and Finite Element Sea ice‐Ocean Model (FESOM) high‐resolution numerical model data. In the region, eddies are thought to play an important role in the redistribution of the warmer and saltier Atlantic Water between the Arctic Ocean and the areas of deep convection in the central Greenland Sea. We found that eddies detected in AVISO and in SAR form two complementary data sets of large mesoscale eddies (with typical radii of 30–50 km) and of small mesoscale/submesoscale eddies (with typical radii of 1–5 km and not exceeding 30 km), respectively. For large mesoscale eddies, the number of cyclones and anticyclones is approximately the same, while for submesoscale eddies, cyclones are strongly dominating. The limitations and possible biases in each of the data sets are discussed and cross‐validated against FESOM results. It is noted that the most energetic eddies are concentrated along the major currents and in the northern part of the region. Eddy translations follow the mean currents in their overall cyclonic circulation around the northern Greenland Sea. A convergence of the eddies toward the Nordbukta area is detected. On seasonal time scale, a higher number of more intense mesoscale eddies is observed during winter, associated with a quasi‐simultaneous intensification of the mean currents. Model results also show an increase in the number of small eddies in spring‐early summer attributed to the decay of large eddies, while in late autumn, the opposite tendency suggests eddy merger.

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The Atlantic Meridional Overturning Circulation in High‐Resolution Models

Cited by 89 publications

References 281 publications

Impact of ocean resolution and mean state on the rate of AMOC weakening

Impact of ocean resolution and mean state on the rate of AMOC weakening

Impact of horizontal resolution on global ocean-sea-ice model simulations based on the experimental protocols of the Ocean Model Intercomparison Project phase 2 (OMIP-2)

Eddies in the North Greenland Sea and Fram Strait From Satellite Altimetry, SAR and High‐Resolution Model Data

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