S. Juricke, S. Danilov, N. Koldunov, M. Oliver, D.V. Sein,
D. Sidorenko, and Q. Wang,
A kinematic kinetic energy backscatter parametrization: From implementation to global ocean simulations,
J. Adv. Model. Earth Syst. 12 (2020), e2020MS002175, doi:10.1029/2020MS002175.
Abstract:
Ocean models at eddy-permitting resolution are generally overdissipative, damping the intensity of the mesoscale eddy field. To reduce overdissipation, we propose a simplified, kinematic energy backscatter parametrization
built into the viscosity operator in conjunction with a new
flow-dependent coefficient of viscosity based on nearest neighbor
velocity differences. The new scheme mitigates excessive dissipation
of energy and improves global ocean simulations at eddy-permitting
resolution. We find that kinematic backscatter substantially raises simulated eddy
kinetic energy, similar to an
alternative, previously proposed dynamic backscatter
parametrization. While dynamic backscatter is scale-aware and
energetically more consistent, its implementation is more
complex. Furthermore, it turns out to be computationally more
expensive, as it applies, among other things, an additional prognostic
subgrid energy equation. The kinematic backscatter proposed here, by
contrast, comes at no additional computational cost, following the
principle of simplicity.
Our primary focus is the discretization on triangular unstructured
meshes with cell placement of velocities (an analog of B-grids), as
employed by the Finite-volumE Sea ice-Ocean Model (FESOM2). The
kinematic backscatter scheme with the new viscosity coefficient is
implemented in FESOM2, and tested in the simplified geometry of a
zonally re-entrant channel as well as in a global ocean simulation on
a 1/4° mesh. This first version of the new kinematic
backscatter needs to be tuned to the specific resolution regime of the
simulation. However, the tuning relies on a single parameter,
emphasizing the overall practicality of the approach.
Download the paper in
PDF
format.