Energetics of lateral eddy diffusion/advection：Part Ⅱ. Numerical diffusion/diffusivity and gravitational potential energy change due to isopycnal diffusion

HUANG Rui Xin

doi:10.1007/s13131-014-0410-0

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HUANG Rui Xin. Energetics of lateral eddy diffusion/advection：Part Ⅱ. Numerical diffusion/diffusivity and gravitational potential energy change due to isopycnal diffusion[J]. Acta Oceanologica Sinica, 2014, 33(3): 19-39. doi: 10.1007/s13131-014-0410-0

Citation:

HUANG Rui Xin. Energetics of lateral eddy diffusion/advection：Part Ⅱ. Numerical diffusion/diffusivity and gravitational potential energy change due to isopycnal diffusion[J]. Acta Oceanologica Sinica, 2014, 33(3): 19-39. doi: 10.1007/s13131-014-0410-0

Citation:

HUANG Rui Xin. Energetics of lateral eddy diffusion/advection：Part Ⅱ. Numerical diffusion/diffusivity and gravitational potential energy change due to isopycnal diffusion[J]. Acta Oceanologica Sinica, 2014, 33(3): 19-39. doi: 10.1007/s13131-014-0410-0

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Energetics of lateral eddy diffusion/advection：Part Ⅱ. Numerical diffusion/diffusivity and gravitational potential energy change due to isopycnal diffusion

doi: 10.1007/s13131-014-0410-0

HUANG Rui Xin

Department of Physical Oceanography, Woods Hole Oceanographic Institution, Woods Hole 02543-1050, USA

Received Date: 2013-08-30
Rev Recd Date: 2013-12-17

Abstract

Abstract

Study of oceanic circulation and climate requires models which can simulate tracer eddy diffusion and advection accurately. It is shown that the traditional Eulerian coordinates can introduce large artificial horizontal diffusivity/viscosity due to the incorrect alignment of the axis. Therefore, such models can smear sharp fronts and introduce other numerical artifacts. For simulation with relatively low resolution, large lateral diffusion was explicitly used in models;therefore, such numerical diffusion may not be a problem. However, with the increase of horizontal resolution, the artificial diffusivity/viscosity associated with horizontal advection in the commonly used Eulerian coordinates may become one of the most challenging obstacles for modeling the ocean circulation accurately. Isopycnal eddy diffusion (mixing) has been widely used in numerical models. The common wisdom is that mixing along isopycnal is energy free. However, a careful examination reveals that this is not the case. In fact, eddy diffusion can be conceptually separated into two steps: stirring and subscale diffusion. Due to the thermobaric effect, stirring, or exchanging water masses, along isopycnal surface is associated with the change of GPE in the mean state. This is a new type of instability, called the thermobaric instability. In addition, due to cabbeling subscale diffusion of water parcels always leads to the release of GPE. The release of GPE due to isopycnal stirring and subscale diffusion may lead to the thermobaric instability.
- Eulerian coordinates,
- numerical diffusivity,
- numerical dissipation,
- energetics of isopycnal eddy diffusion

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References(26)

References

Bryan F. 1987. Parameter sensitivity of primitive equation ocean circulation models. J Phys Oceanogr, 17: 970-984

Carton J A, Giese B S. 2008. A reanalysis of ocean climate using simple ocean data assimilation (SODA). Mon Weather Rev, 136: 2999-3017

Conkright M E, Locarnini R A, Garcia H E, et al. 2002. World Ocean Atlas 2001: Objective analysis, data statistics, and figures, CD-ROM Documentation. National Oceanographic Data Center, Silver Spring, MD, 17

Eden C, Willebrand J. 1999. Neutral density revisited. Deep-Sea Res Pt II, 46: 33-54

Forster T D, Carmack E C. 1976. Frontal zone mixing and Antarctic bottom water formation in the southern Weddell Sea. Deep-Sea Res, 23: 301-317

Gent P R, McWilliams J C. 1990. Isopycnal mixing in ocean circulation models. J Phys Oceanogr, 20: 150-155

Huang R X. 2014a. Adiabatic density surface, neutral density surface, potential density surface and mixing path. Manuscript submitted to Journal of tropical oceanography

Huang R X. 2014b. Energetics of lateral eddy diffusion/advection: Part Ⅰ. Thermodynamics and energetics of vertical eddy diffusion. Acta Oceanol Sin, 33 (3): 1-18

Hui W H. 2007. The unified coordinate system in computational fluid dynamics. Commu Compu Phys, 2: 577-610

Hui W H, Li P Y, Li Z W. 1999. A unified coordinate system for solving the two-dimensional Euler equations. J Comput Phys, 153: 596

Hui W H, Kudriakov S. 2001. A unified coordinate system for solving the three-dimensional Euler equations. J Comput Phys, 172: 235

Hui W H, Xu K. 2012. Computational Fluid Dynamics Based On The Unified Coordinates. Beijing: Science Press, 198

McDougall T J. 1987a. Neutral surfaces. J Phys Oceanogr, 17: 1950-1964

McDougall T J. 1987b. The vertical motion of submesoscale coherent vorticies across neutral surfaces. J Phys Oceanogr, 17: 2334-2342

McDougall T J. 1987c. Thermobaricity, cabbeling, and water-mass conversion. J Geophys Res, 92: 5448-5464

Nycander N. 2011. Energy conversion, mixing energy, and neutral surfaces with a nonlinear equation of state. J Phys Oceanogr, 41: 28-41

Ledwell J R, Watson A J, Law C S. 1998. Mixing of a tracer in the pycnocline. J Geopys Res, 103: 21499-21529

Lumpkin R, Treguier A-M, Speer K. 2002. Lagrangian eddy scales in the Northern Atlantic Ocean. J Phys Oceanogr, 32: 2425-2440

Obuko A. 1971: Oceanic diffusion diagrams. Deep-Sea Res, 18: 789-802

Qian Y-K, Peng S, Li Y. 2013. Eulerian and Lagrangian statistics in the South China Sea as deduced from surface drifters. J Phys Oceanogr, 43: 726-743

Ruddick B, Kerr O. 2003: Oceanic thermohaline intrusions: theory. Progr Oceanogr, 56: 483-497

Ruddick B, Richards K. 2003: Oceanic thermohaline intrusions: observations. Progr Oceanogr, 56: 499-527

Spivakovskaya D, Heemink A W, Deleersnijder E. 2007. Lagrangian modelling of multi-dimensional advection-diffusion with space-varying diffusivities: theory and idealized test cases, 57(3): 189-203

Tulloch R, Ferrari R, Jahn O, et al. 2013. Direct estimate of lateral eddy diffusivity upstream of Drake Passage, manuscript

Wagner D H. 1987. Equivalence of Eulerian and Lagrangian equations of gas dynamics for weak solutions. J Differ Equations, 68: 118-136

Zheng C, Wang P P. 1999. MT3DMS: a modular three-dimensional multispecies transport model for simulation of advection, dispersion and chemical reactions of contaminants in groundwater systems;documentation and user's guide. Alabama Univ University

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