Abstract
Abstract. A practical scheme is proposed to explicitly introduce tides into ocean general circulation models (OGCM). In this scheme, barotropic linear response to the tidal forcing is calculated by the time differential equations modified for ocean tides, instead of the original barotropic equations of an OGCM. This allows for the usage of various parameterizations specified for tides, such as the self-attraction/loading (SAL) effect and energy dissipation due to internal tides, without unintentional violation of the original dynamical balances in an OGCM. Meanwhile, secondary nonlinear effects of tides, e.g., excitation of internal tides and advection by tidal currents, are fully represented within the framework of the original OGCM equations. That is, this scheme drives the OGCM by the barotropic linear tidal currents which are predicted progressively by a tuned tide model, instead of the equilibrium tide potential, without large additional numerical costs. We incorporated this scheme into Meteorological Research Institute Community Ocean Model and executed test experiments with a low-resolution global model. The results showed that the model can simulate both the non-tidal circulations and the tidal motion simultaneously. Owing to the usage of tidal parameterizations such as a SAL term, a root-mean-squared error in the tidal heights is found to be as small as 10.0 cm, which is comparable to that of elaborately tuned tide models. In addition, analysis of the speed and energy of the barotropic tidal currents is found to be consistent with that of past tide studies. The model also showed active excitement of internal tides and tidal mixing. In the future, the impacts of internal tides and tidal mixing should be examined using a model with a finer resolution, since explicit and precise introduction of tides into an OGCM is a significant step toward the improvement of ocean models.
Highlights
Recent advances in theories of ocean general circulations and observations of deep seas have revealed that tides play a significant role in open oceans as well as in coastal areas
Simulation output of the linear tidal component, ηlt, may serve as a basic data set of tides in an ocean general circulation models (OGCM), since this component represents most of the tidal put of η, the tidal heights can be estimated by the anomaly from the 25-hour running mean, or the deviation from the dynamic heights after Arbic et al (2010)
Since reproducibility of internal tides depends strongly on model resolution (Niwa and Hibiya, 2011), this difference suggests that our model resolution of 1◦ × 1/2◦
Summary
Recent advances in theories of ocean general circulations and observations of deep seas have revealed that tides play a significant role in open oceans as well as in coastal areas. Munk and Wunsch (1998) suggested that vertical mixing in deep seas due to breaking of internal tides is an important process in the global thermohaline circulations. This hypothesis is supported by the fact that a large part of the tidal energy is dissipated in deep seas (Egbert and Ray, 2001; St. Laurent and Garrett, 2002; Niwa and Hibiya, 2011). One reason is that most OGCMs could not represent tides since they adopted the rigid-lid condition to preclude the surface gravity waves due to the CourantFriedrichs-Lewy condition.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
