Abstract
AbstractTraditional parameterizations of convection are a large source of error in weather and climate prediction models, and the assumptions behind them become worse as resolution increases. Multifluid modeling is a promising new method of representing subgrid‐scale and near‐grid‐scale convection allowing for net mass transport by convection and nonequilibrium dynamics. The air is partitioned into two or more fluids, which may represent, for example, updrafts and the nonupdraft environment. Each fluid has its own velocity, temperature, and constituents with separate equations of motion. This paper presents two‐fluid Boussinesq equations for representing subgrid‐scale dry convection with sinking and w = 0 air in Fluid 0 and rising air in Fluid 1. Two vertical slice test cases are developed to tune parameters and to evaluate the two‐fluid equations: a buoyant rising bubble and radiative convective equilibrium. These are first simulated at high resolution with a single‐fluid model and conditionally averaged based on the sign of the vertical velocity. The test cases are next simulated with the two‐fluid model in one column. A model for entrainment and detrainment based on divergence leads to excellent representation of the convective area fraction. Previous multifluid modeling of convection has used the same pressure for both fluids. This is shown to be a bad approximation, and a model for the pressure difference between the fluids based on divergence is presented.
Highlights
Slow progress has been made improving the parameterization of subgrid-scale convection since Arakawa and Schubert (1974), Tiedtke (1989), Gregory and Rowntree (1990), and Kain and Fritsch (1990)
Traditional parameterizations of convection are a large source of error in weather and climate prediction models, and the assumptions behind them become worse as resolution increases
Multifluid modeling is a promising new method of representing subgrid-scale and near-grid-scale convection allowing for net mass transport by convection and nonequilibrium dynamics
Summary
Slow progress has been made improving the parameterization of subgrid-scale convection since Arakawa and Schubert (1974), Tiedtke (1989), Gregory and Rowntree (1990), and Kain and Fritsch (1990). Improvements have been made by relaxing the quasi-equilibrium assumption (Gerard & Geleyn, 2005; Pan & Randall, 1998; Park, 2014), including stochasticity (Plant & Craig, 2008) and allowing net mass transport by convection (Kuell & Bott, 2008; Malardel & Bechtold, 2019). This paper presents the multifluid Boussinesq equations for representing subgrid-scale convection including a parameterization of the pressure difference between fluids (section 2.2) and a new model of entrainment and detrainment (section 2.3). These are first simulated at high resolution in a single fluid model, and statistics of the flow are reproduced solving the two-fluid equations in one column
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