2021
DOI: 10.1029/2020gl091719
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Complexity of Mesoscale Eddy Diffusivity in the Ocean

Abstract: Stirring of water by mesoscale currents (“eddies”) leads to large‐scale transport of many important oceanic properties (“tracers”). These eddy‐induced transports can be related to the large‐scale tracer gradients, using the concept of turbulent diffusion. The concept is widely used to describe these transports in the real ocean and to represent them in climate models. This study focuses on the inherent complexity of the corresponding coefficient tensor (“K‐tensor”) and its components, defined here in all its s… Show more

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Cited by 23 publications
(35 citation statements)
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References 58 publications
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“…Using a quasigeostrophic model, Haigh et al (2021a) defined eddies and large scales using a spatial filter and found that the diffusion axis has complicated spatial and temporal dependence, but that it tends to align with the large-scale flow, agreeing with earlier studies. Another key finding was that the eigenvalues of the diffusion tensor S are arranged in opposite-signed pairs, as was also found with comprehensive GCMs (Stanley, Bachman & Grooms 2020;Kamenkovich et al 2021). Haigh et al (2020) confirmed that opposite-signed eigenvalues were a robust feature for a selection of spatial filter sizes and for eddy fluxes in a Reynolds eddy decomposition.…”
Section: Introductionsupporting
confidence: 70%
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“…Using a quasigeostrophic model, Haigh et al (2021a) defined eddies and large scales using a spatial filter and found that the diffusion axis has complicated spatial and temporal dependence, but that it tends to align with the large-scale flow, agreeing with earlier studies. Another key finding was that the eigenvalues of the diffusion tensor S are arranged in opposite-signed pairs, as was also found with comprehensive GCMs (Stanley, Bachman & Grooms 2020;Kamenkovich et al 2021). Haigh et al (2020) confirmed that opposite-signed eigenvalues were a robust feature for a selection of spatial filter sizes and for eddy fluxes in a Reynolds eddy decomposition.…”
Section: Introductionsupporting
confidence: 70%
“…A diffusion tensor can be employed to account for the anisotropy, while simplified diagonal tensors can only have directions of preferential eddy diffusion aligned with the model grid and scalar diffusivities cannot account for anisotropy at all. Recent studies (Haigh et al 2020(Haigh et al , 2021aStanley et al 2020;Kamenkovich et al 2021) have diagnosed the diffusion tensor in both idealised models and realistic GCMs and found it to be characterised by opposite-signed eigenvalues. These diagnoses of opposite-signed eigenvalues suggest that the anisotropy is more pronounced than previously thought.…”
Section: Discussionmentioning
confidence: 99%
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“…where μ j are the corresponding eigenvalues of L. Therefore, what the authors of [92] have proposed can be though as an index related to the solution of the backward diffusion equation, i.e., negative time, or as a diffusion equation with negative diffusivity D < 0 [65]. There are physical situations in which such negative diffusivity appears [48,140,173,225,226]. For instance, in the simultaneous diffusion of boron and point defect in silicon, the diffusivities of interstitial could be negative [225].…”
Section: Laplacian Estrada Index and Backward Diffusionmentioning
confidence: 99%
“…This raises an important question on whether K is unique, given that it can be estimated from an ensemble of many different tracer concentration pairs. The answer is negative (Kamenkovich et al 2021;Sun et al 2021), and how to interpret this uncovered non-uniqueness remains an open problem. In this paper we will address and get around it, in the context of dynamically active tracers constrained by the potential vorticity (PV) conservation law.…”
Section: Introductionmentioning
confidence: 99%