Your search keyword '"MATHEMATICAL models of fluid dynamics"' showing total 2 results

1. Precise Calculations of the Existence of Multiple AMOC Equilibria in Coupled Climate Models. Part I: Equilibrium States.

Author

Sijp, Willem P., England, Matthew H., and Gregory, Jonathan M.

Subjects

*ATLANTIC meridional overturning circulation, *SALINITY, *CLIMATOLOGY, *MATHEMATICAL models of fluid dynamics, *NUMERICAL analysis, *HEAT transfer

Abstract

This study examines criteria for the existence of two stable states of the Atlantic Meridional Overturning Circulation (AMOC) using a combination of theory and simulations from a numerical coupled atmosphere-ocean climate model. By formulating a simple collection of state parameters and their relationships, the authors reconstruct the North Atlantic Deep Water (NADW) OFF state behavior under a varying external salt-flux forcing. This part (Part I) of the paper examines the steady-state solution, which gives insight into the mechanisms that sustain the NADW OFF state in this coupled model; Part II deals with the transient behavior predicted by the evolution equation. The nonlinear behavior of the Antarctic Intermediate Water (AAIW) reverse cell is critical to the OFF state. Higher Atlantic salinity leads both to a reduced AAIW reverse cell and to a greater vertical salinity gradient in the South Atlantic. The former tends to reduce Atlantic salt export to the Southern Ocean, while the latter tends to increases it. These competing effects produce a nonlinear response of Atlantic salinity and salt export to salt forcing, and the existence of maxima in these quantities. Thus the authors obtain a natural and accurate analytical saddle-node condition for the maximal surface salt flux for which a NADW OFF state exists. By contrast, the bistability indicator proposed by De Vries and Weber does not generally work in this model. It is applicable only when the effect of the AAIW reverse cell on the Atlantic salt budget is weak. [ABSTRACT FROM AUTHOR]

Published

2012

2. Adaptation of the vertical resolution in the mixed layer for HYCOM

Author

Renaudie, Cécile, Baraille, Rémy, Morel, Yves, Hello, Gwenaëlle, and Giordani, Hervé

Subjects

*ATMOSPHERIC boundary layer, *OCEAN circulation, *MATHEMATICAL models of fluid dynamics, *OCEAN convection, *HYDRODYNAMICS, *ERROR analysis in mathematics

Abstract

Abstract: This paper focuses on the dynamics of the mixed layer. When the mixed layer depth increases, the vertical discretisation eventually becomes too sparse at the bottom of this layer to accurately resolve its evolution and strong numerical errors can appear. This is linked to the fact that the vertical resolution is concentrated in the upper part of the ocean and does not adapt to the deepening of the mixed layer. Knowing that the HYbrid Coordinate Ocean Model (HYCOM) is able to modify the distribution of the vertical levels, we suggest in this paper a method to adapt the resolution to the mixed layer extension. This method is tested in 1-D configurations for two academic atmospheric forcing conditions (strong convection and wind-mixing) and a realistic forcing extending over one year, with seasonal restratification following strong winter convection. The new method improves the results in all cases, and in particular when the mixed layer reaches deep layers. [Copyright &y& Elsevier]

Published

2009