Reconciling the observed mid-depth exponential ocean stratification with weak interior mixing and Southern Ocean dynamics via boundary-intensified mixing

Munk (Deep Sea Res Oceanogr Abstr 13(4):707–730, 1966) showed that the mid-depth (1–3 km) vertical temperature profile is consistent with a one-dimensional vertical advection–diffusion balance, with a constant upwelling and an interior diapycnal diffusivity of O ( 10 - 4 ) m 2 s - 1 . However, typic...

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Bibliographic Details
Published in:European physical journal plus 2020-04, Vol.135 (4), p.375, Article 375
Main Authors: Miller, Madeline D., Yang, Xiaoting, Tziperman, Eli
Format: Article
Language:English
Subjects:
Advection
Applied and Technical Physics
Atomic
Complex Systems
Condensed Matter Physics
Deep sea
Diffusivity
Eddies
Focus Point on Fundamental and Open Issues in Climate Dynamics
Mathematical and Computational Physics
Molecular
Ocean dynamics
Oceanic general circulation model
Optical and Plasma Physics
Outcrops
Physics
Physics and Astronomy
Regular Article
Stratification
Surface water
Temperature profiles
Theoretical
Upwelling
Water depth
Wind
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Summary:Munk (Deep Sea Res Oceanogr Abstr 13(4):707–730, 1966) showed that the mid-depth (1–3 km) vertical temperature profile is consistent with a one-dimensional vertical advection–diffusion balance, with a constant upwelling and an interior diapycnal diffusivity of O ( 10 - 4 ) m 2 s - 1 . However, typical observed diffusivities in the interior are O ( 10 - 5 ) m 2 s - 1 . Recent work suggested that the mid-depth stratification is set by Southern Ocean (SO) isopycnal slopes, governed by SO wind and eddies, that communicate the surface outcrop positions to the mid-depth ocean. It is shown here, using an idealized ocean general circulation model, that while SO dynamics play an important role by linking the surface water mass transformation by air-sea fluxes with the mid-depth interior stratification, they do not set the observed exponential stratification and that interior mixing must contribute. Strong diapycnal mixing concentrated near the ocean boundaries is shown to be balanced locally by upwelling. A one-dimensional Munk-like balance in these boundary-mixing areas, although with much larger mixing and upwelling, leads to an exponential mid-depth temperature stratification, which spreads via isopycnal advection and mixing to the ocean interior. The exponential profile is robust to vertical variations in the vertical velocity and persists despite the observed weak interior diapycnal mixing. These results may suggest a way to reconcile the observed exponential interior mid-depth temperature stratification, the weak diapycnal diffusivity observed in tracer release experiments, and the role of Southern Ocean dynamics.
ISSN:2190-5444
2190-5444
DOI:10.1140/epjp/s13360-020-00375-y