Implementing the HYbrid MAss flux Convection Scheme (HYMACS) in ICON – First idealized tests and adaptions to the dynamical core for local mass sources

Langguth, Michael; Kuell, V.; Bott, Andreas

doi:10.1002/qj.3812

Cited by 2 publications

(2 citation statements)

References 85 publications

(123 reference statements)

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“…Although parameterizations with relaxed fractional area occupied by the convection have been formulated (e.g. Arakawa and Wu, 2013;Grell and Freitas, 2014;Fan et al, 2015;Gerard, 2015;Zheng et al, 2016;Kwon and Hong, 2017;Malardel and Bechtold, 2019;Langguth et al, 2020;Wang, 2022), they still assume top-hat profiles as in the mass-flux formulation, and as is going to be seen in Section 4.3.1, such development is valid only if the convective radial velocity is assumed to be very small, and thus, the subgrid fluxes containing subgrid horizontal wind components, such as the subgrid horizontal transport, are neglected. However, at high resolutions, there might be a large variability between two consecutive grid cells (for example, in a grid cell a cumulonimbus cloud may develop, while in the neighbor one only shallow convection is present), and thus, neglecting the subgrid horizontal transport terms might result in large errors.…”

Section: Introductionmentioning

confidence: 99%

Generalized eddy-diffusivity mass-flux (GEM) formulation for the parameterization of atmospheric convection and turbulence

Vraciu

2024

Preprint

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Section: Introductionmentioning

confidence: 99%

Generalized eddy-diffusivity mass-flux (GEM) formulation for the parameterization of atmospheric convection and turbulence

Vraciu

2024

Preprint

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“…However, the assumption of a very small fractional area occupied by the convection in every grid box of the numerical model is still a very important assumption in all mass‐flux formations (Arakawa & Wu, 2015; Yano, 2014b), which means that the grid spacing of the numerical models must be large enough such that this condition is respected regardless of the spatial variability of the convective elements. Although parametrizations with relaxed fractional area occupied by the convection have been formulated (e.g., Arakawa & Wu, 2013; Fan, 2015; Gerard, 2015; Grell & Freitas, 2014; Kwon & Hong, 2017; Langguth et al, 2020; Malardel & Bechtold, 2019; Wang, 2022; Zheng et al, 2016), they still assume top‐hat profiles as in the mass‐flux formulation; and as is going to be seen in Section 4.3.1, such development is valid only if the convective radial velocity is assumed to be very small, and thus the subgrid fluxes containing subgrid horizontal wind components, such as the subgrid horizontal transport, are neglected. However, at high resolutions, there might be a large variability between two consecutive grid cells (e.g., in a grid cell a cumulonimbus cloud may develop, whereas in the neighbor cell only shallow convection is present), and thus neglecting the subgrid horizontal transport terms might result in large errors.…”

Section: Introductionmentioning

confidence: 99%

Generalized eddy‐diffusivity mass‐flux formulation for the parametrization of atmospheric convection and turbulence

Vraciu

2024

Quart J Royal Meteoro Soc

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The atmospheric convection is a phenomenon that has a length scale smaller than the resolution at which the state‐of‐the‐art general circulation numerical models are running, and thus the convection needs to be parametrized. In this work, a theoretical formulation for the parametrization of subgrid‐scale convection based on subgrid averaging that represents a generalized eddy‐diffusivity mass‐flux formulation is presented. The subgrid fluxes are derived by considering a decomposition of subgrid variables into convective and turbulent variables, and by assuming that the convection is modeled by round convective plumes with generic radial profiles. The main difference between our formulation and the mass‐flux formulations is that the condition of a very small fractional area occupied by the convection is replaced with the condition that the convective vertical velocity goes to the mean state far from the updraft region of the plume. The plume model can also be generalized by considering that the convective elements are energy‐consistent plumes, governed by the conservation of mass, momentum, kinetic energy, and buoyancy, which provides a physical‐based closure for the entrainment. Therefore, the closing problem of our formulation consists of the specification of the convective radial profiles and the boundary conditions at the initial vertical level. Furthermore, our formulation allows one to consider more realistic profiles for the convective variables, making the formulation suitable for the parametrization of atmospheric convection at the convective gray zone. This aspect is discussed in the last part of this work, where it is showed how the formulation can be implemented at any resolution. Moreover, in the present framework, no distinct assumptions are required for each convective type, thus facilitating the parametrization of convection in a unified way.

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Implementing the HYbrid MAss flux Convection Scheme (HYMACS) in ICON – First idealized tests and adaptions to the dynamical core for local mass sources

Cited by 2 publications

References 85 publications

Generalized eddy-diffusivity mass-flux (GEM) formulation for the parameterization of atmospheric convection and turbulence

Generalized eddy-diffusivity mass-flux (GEM) formulation for the parameterization of atmospheric convection and turbulence

Generalized eddy‐diffusivity mass‐flux formulation for the parametrization of atmospheric convection and turbulence

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