The role of Atlantic overturning circulation in the recent decline of Atlantic major hurricane frequency

Geophysical Research Letters

Knutson

2019

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Atlantic Multidecadal Variability (AMV) is a multivariate phenomenon. Here for the first time we obtain a multivariate AMV index and associated patterns using Multivariate Empirical Orthogonal Function (MEOF) analysis to explore the multivariate nature of AMV. Coherent multidecadal variability that is unique to the Atlantic is found in the observed MEOF‐extracted AMV, various AMV‐related indices, and an Atlantic Meridional Overturning Circulation fingerprint. When the signal associated with global mean sea surface temperature is removed from both observations and Coupled Model Intercomparison Project Phase 5 (CMIP5) simulations, the residual CMIP5 forced basin‐wide sea surface temperature‐based AMV index disagrees strongly with the observed residual. Only the observed residual basin‐wide sea surface temperature‐based AMV index retains a strong AMV signal. The MEOF approach still extracts a residual CMIP5 forced AMV signal that is unique to the Atlantic, although very different from observations. Our findings suggest that the observed AMV is not dominated by external forcing.

Section: Relationship Between Amv and Amoc Fingerprintsupporting

confidence: 85%

A Multivariate AMV Index and Associated Discrepancies Between Observed and CMIP5 Externally Forced AMV

Yan

Geophysical Research Letters

Knutson

2019

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“…The directly observed AMOC at 26°N from the RAPID program exhibits a significant downward shift over the recent decade since 2004, which has been widely interpreted as arising from intrinsic decadal/multidecadal AMOC variability and a reversal from the previous AMOC strengthening (e.g., Jackson et al, ; Robson, Hodson, et al, ; Robson et al, ; Smeed et al, , ; Yan et al, , ). The total reduction of the directly observed AMOC at 26°N between 2004–2009 and 2009–2014 is 2.9 Sv and is statistically significant (Frajka‐Williams et al, ).…”

Section: Amoc‐amv Linkagementioning

confidence: 99%

“…Reviews of Geophysics Robson et al, 2016;Smeed et al, 2018;Yan et al, 2017). In a recent study, the high correlation between the observed AMV index (based on linearly detrended basin-averaged low-pass-filtered North Atlantic SST anomalies) and the simulated ensemble mean AMV index from a large ensemble of twentieth-century…”

Section: 1029/2019rg000644mentioning

confidence: 99%

A Review of the Role of the Atlantic Meridional Overturning Circulation in Atlantic Multidecadal Variability and Associated Climate Impacts

Sutton

Danabasoglu

et al. 2019

Reviews of Geophysics

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390

362

By synthesizing recent studies employing a wide range of approaches (modern observations, paleo reconstructions, and climate model simulations), this paper provides a comprehensive review of the linkage between multidecadal Atlantic Meridional Overturning Circulation (AMOC) variability and Atlantic Multidecadal Variability (AMV) and associated climate impacts. There is strong observational and modeling evidence that multidecadal AMOC variability is a crucial driver of the observed AMV and associated climate impacts and an important source of enhanced decadal predictability and prediction skill. The AMOC‐AMV linkage is consistent with observed key elements of AMV. Furthermore, this synthesis also points to a leading role of the AMOC in a range of AMV‐related climate phenomena having enormous societal and economic implications, for example, Intertropical Convergence Zone shifts; Sahel and Indian monsoons; Atlantic hurricanes; El Niño–Southern Oscillation; Pacific Decadal Variability; North Atlantic Oscillation; climate over Europe, North America, and Asia; Arctic sea ice and surface air temperature; and hemispheric‐scale surface temperature. Paleoclimate evidence indicates that a similar linkage between multidecadal AMOC variability and AMV and many associated climate impacts may also have existed in the preindustrial era, that AMV has enhanced multidecadal power significantly above a red noise background, and that AMV is not primarily driven by external forcing. The role of the AMOC in AMV and associated climate impacts has been underestimated in most state‐of‐the‐art climate models, posing significant challenges but also great opportunities for substantial future improvements in understanding and predicting AMV and associated climate impacts.

“…These phenomena include synopticscale tropical waves (e.g., Thorncroft & Hodges, 2001), tropical intraseasonal variability (e.g., Maloney & Hartmann, 2000), interannual sea surface temperature (SST) variability (Chen & Lin, 2011), and Atlantic multidecadal variability involving the Atlantic meridional overturning circulation (e.g., Goldenberg et al, 2001;Gray, 1984;Yan et al, 2017). These phenomena include synopticscale tropical waves (e.g., Thorncroft & Hodges, 2001), tropical intraseasonal variability (e.g., Maloney & Hartmann, 2000), interannual sea surface temperature (SST) variability (Chen & Lin, 2011), and Atlantic multidecadal variability involving the Atlantic meridional overturning circulation (e.g., Goldenberg et al, 2001;Gray, 1984;Yan et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Impacts of Extratropical Weather Perturbations on Tropical Cyclone Activity: Idealized Sensitivity Experiments With a Regional Atmospheric Model

Geophysical Research Letters

Knutson

Garner

2019

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Extratropical weather perturbations have been linked to Atlantic tropical cyclones (TCs) activity in observations. However, modeling studies of the extratropical impact are scarce and disagree about its importance and climate implications. Using a nonhydrostatic regional atmospheric model, we explore the extratropical impact by artificially suppressing extratropical weather perturbations at the tropical-extratropical interface. Our 22-year simulations of August-October suggest that the extratropical suppression adds~3.7 Atlantic TCs per season on average, although the response varies among individual years. The TC response mainly appears within 30-40°N, where tropical cyclogenesis frequency quadruples compared to control simulations. This increased cyclogenesis, accompanied by a strong increase of midtropospheric relative humidity, arises as the perturbation suppression reduces the extratropical interference of TC development. The suppression of extratropical perturbations is highly idealized but may suggest mechanisms by which extratropical atmospheric variability potentially influences TC activity in past or future altered climate states. Plain Language SummaryRecent observational studies suggest that Atlantic hurricane activity is strongly affected by extratropical weather processes, but modeling studies disagree about the importance of such an impact. Using a regional atmospheric model, we conduct idealized experiments to explore the extratropical impact on Atlantic hurricane activity. Our simulations of 22 hurricane seasons show that artificially suppressing extratropical weather perturbations at the northern boundary in the model can increase hurricane activity significantly. The response of the model's hurricane activity varies from season to season, which may contribute to the different responses found among earlier modeling studies. Notably, the strongest response of hurricane activity appears within 30-40°N, where the number of hurricane formations quadruples compared to reference simulations. The perturbation reduction also helps hurricanes to move more slowly and smoothly with fewer disruptions from the high latitudes. These experiments, though idealized, suggest that the extratropical atmospheric circulation plays an important moderating role in limiting Atlantic hurricane formation. These experiments also could have implications for hurricane activity in the distant past or in coming decades, for example, if climate warming were accompanied by a weakening or poleward shift of extratropical weather systems.