Water mass distribution and ventilation time scales in a cost-efficient, 3-dimensional ocean model
A cost-efficient, seasonally forced 3-dimensional frictional-geostrophic balance ocean model (Bern3D) has been developed that features isopycnal diffusion and Gent-McWilliams transport parameterization, 32 depth layers, and an implicit numerical scheme for the vertical diffusion. It has been tuned t...
| Main Authors: | , , , |
|---|---|
| Format: | Article in Journal/Newspaper |
| Language: | unknown |
| Published: |
2006
|
| Subjects: | |
| Online Access: | https://oro.open.ac.uk/25676/ https://oro.open.ac.uk/25676/1/mueller06jc-bern3d.pdf http://journals.ametsoc.org/toc/clim/19/21 |
| Summary: | A cost-efficient, seasonally forced 3-dimensional frictional-geostrophic balance ocean model (Bern3D) has been developed that features isopycnal diffusion and Gent-McWilliams transport parameterization, 32 depth layers, and an implicit numerical scheme for the vertical diffusion. It has been tuned towards observed CFC-11 inventories and deep ocean radiocarbon signatures to reproduce the ventilation time scales of the thermocline and the deep ocean. Model results are consistent with the observed large-scale distributions of temperature, salinity, natural and bomb- produced radiocarbon, CFC-11, anthropogenic carbon, 39Ar/Ar and estimates of the meridional heat transport. Root mean square errors for the temperature and salinity fields are 1 K and 0.2 psu, comparable to results from the Ocean Carbon-Cycle Model Intercomparison Project. Global inventories of CFC-11 and anthropogenic carbon agree closely with observation-based estimates. Model weaknesses include a too weak formation and propagation of Antarctic Intermediate Water and of North Atlantic Deep Water. The model has been applied to quantify the recent carbon balance, surface-to-deep transport mechanisms, and the importance of vertical resolution for deep equatorial upwelling. Advection is a dominant surface-to-deep transport mechanism, whereas explicit diapycnal mixing is of little importance for passive tracers and contributes less than three percent to the modeled CFC-11 inventory in the Indo-Pacific. Decreasing the vertical resolution from 32 to 8 layers causes deep equatorial upwelling to increase by more than a factor of four. Modeled ocean uptake of anthropogenic carbon is 19.7 GtC over the decade from 1993 to 2003, comparable to an estimate from atmospheric oxygen data of 22.4 ± 6.1 GtC. |
|---|