Abstract
Abstract. The accurate modeling of cascades to unresolved scales is an important part of the tracer transport component of dynamical cores of weather and climate models. This paper aims to investigate the ability of the advection schemes in the National Center for Atmospheric Research's Community Atmosphere Model version 5 (CAM5) to model this cascade. In order to quantify the effects of the different advection schemes in CAM5, four two-dimensional tracer transport test cases are presented. Three of the tests stretch the tracer below the scale of coarse resolution grids to ensure the downscale cascade of tracer variance. These results are compared with a high resolution reference solution, which is simulated on a resolution fine enough to resolve the tracer during the test. The fourth test has two separate flow cells, and is designed so that any tracer in the western hemisphere should not pass into the eastern hemisphere. This is to test whether the diffusion in transport schemes, often in the form of explicit hyper-diffusion terms or implicit through monotonic limiters, contains unphysical mixing. An intercomparison of three of the dynamical cores of the National Center for Atmospheric Research's Community Atmosphere Model version 5 is performed. The results show that the finite-volume (CAM-FV) and spectral element (CAM-SE) dynamical cores model the downscale cascade of tracer variance better than the semi-Lagrangian transport scheme of the Eulerian spectral transform core (CAM-EUL). Each scheme tested produces unphysical mass in the eastern hemisphere of the separate cells test.
Highlights
The role of diffusion in dynamical cores of general circulation models (GCMs) is very complex, as it is often used for both physical reasons and numerical reasons (Jablonowski and Williamson, 2011)
The results show that the finite-volume (CAM-FV) and spectral element (CAM-SE) dynamical cores model the downscale cascade of tracer variance better than the semi-Lagrangian transport scheme of the Eulerian spectral transform core (CAM-EUL)
In this paper we investigate the cascade to subgrid scales in the tracer transport component of dynamical cores, focusing on the dynamical cores of the National Center for Atmospheric Research’s (NCAR) Community Atmosphere Model version 5 (CAM5) (Neale et al, 2010)
Summary
The role of diffusion in dynamical cores of general circulation models (GCMs) is very complex, as it is often used for both physical reasons and numerical reasons (Jablonowski and Williamson, 2011). One area of interest is how dynamical cores represent the effects of subgrid scales. Dynamical cores generally use a fixed grid of finite grid spacing, there are many different types of grids that can be applied to spherical geometry (Williamson, 2007; Staniforth and Thuburn, 2012). Any scales smaller than the grid spacing cannot be represented explicitly in the dynamical core. In this paper we investigate the cascade to subgrid scales in the tracer transport component of dynamical cores, focusing on the dynamical cores of the National Center for Atmospheric Research’s (NCAR) Community Atmosphere Model version 5 (CAM5) (Neale et al, 2010)
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