Open-ocean tides simulated by ICON-O, version icon-2.6.6

This paper evaluates barotropic tides simulated by a newly developed multi-layer ocean general circulation, ICON-O, and assesses processes and model configurations that can impact the quality of the simulated tides. Such an investigation is crucial for applications addressing internal tides that are...

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Bibliographic Details
Published in:Geoscientific Model Development 2023-09, Vol.16 (17), p.5179-5196
Main Authors: von Storch, Jin-Song, Hertwig, Eileen, Lüschow, Veit, Brüggemann, Nils, Haak, Helmuth, Korn, Peter, Singh, Vikram
Format: Article
Language:English
Subjects:
Barotropic mode
Barotropic tides
Configurations
Error analysis
Experiments
General circulation models
Geographical distribution
Inhomogeneity
Internal tides
Modelling
Multilayers
Ocean circulation
Ocean tides
Oceanic general circulation model
Oceans
Parameterization
Parameters
Shallow water
Simulation
Telescoping
Tidal dynamics
Tides
Topographic waves
Topography
Wave drag
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Summary:This paper evaluates barotropic tides simulated by a newly developed multi-layer ocean general circulation, ICON-O, and assesses processes and model configurations that can impact the quality of the simulated tides. Such an investigation is crucial for applications addressing internal tides that are much more difficult to evaluate than the barotropic tides. Although not specially tuned for tides and not constrained by any observations, ICON-O is capable of producing the main features of the open-ocean barotropic tides as described by the geographical distributions of amplitude, phase, and amphidromic points. An error analysis shows, however, that the open-ocean tides simulated by ICON-O are less accurate than those simulated by two other ocean general circulation models (OGCMs), especially when not properly adjusting the time step and the parameters used in the time-stepping scheme. Based on a suite of tidal experiments, we show that an increase in horizontal resolution only improves tides in shallow waters. Relevant for using ICON-O with its telescoping grid capacity, we show that spatial inhomogeneity does not deteriorate the quality of the simulated tides. We further show that implementing a parameterization of topographic wave drag improves the quality of the simulated tides in deep ocean independent of the model configuration used, whereas the implementation of a self-attraction and loading (SAL) parameterization in a low-resolution (40 km) version of ICON-O degrades the quality of tides in shallow ocean. Finally, we show that the quality of tides simulated by ICON-O with low resolution (40 km) can be significantly improved by adjusting the time step or the parameters in the time-stepping scheme used for obtaining the model solution.
ISSN:1991-9603
1991-959X
1991-962X
1991-9603
1991-962X
DOI:10.5194/gmd-16-5179-2023