Abstract
The ascent of a moist thermal is used to test a recently developed essentially Lagrangian model for simulating moist convection. In this Moist‐Parcel‐In‐Cell (MPIC) model, a number of parcels are used to represent the flow in each grid cell. This has the advantage that the parcels provide an efficient and explicit representation of subgrid‐scale flow. The model is compared against Eulerian large‐eddy simulations with a version of the Met Office NERC Cloud model (MONC) which solves the same equations in a more traditional Eulerian scheme. Both models perform the same idealized simulation of the effects of latent heat release and evaporation, rather than a specific atmospheric regime.Dynamical features evolve similarly throughout the development of the thermal using the two approaches. Subgrid‐scale properties of small‐scale eddies captured by the MPIC model can be explicitly reconstructed on a finer grid. MPIC simulations thus resolve smaller features when using the same grid spacing as MONC, which is useful for detailed studies of turbulence in clouds.The convergence of bulk properties is also used to compare the two models. Most of these properties converge rapidly, though the probability distribution function of liquid water converges only slowly with grid resolution in MPIC. This may imply that the current implementation of the parcel mixing mechanism underestimates small‐scale mixing.Finally, it is shown how Lagrangian parcels can be used to study the origin of cloud air in a consistent manner in MPIC.
Highlights
Detailed studies of moist convection continue to play an important role in the development of weather and climate models
D18 describe the way in which buoyancy and mixing are represented in the MPIC framework. We argue that this approach has advantages for modelling cumulus convection, further improvements may be possible
The development of a warm, moist thermal was simulated in a novel essentially Lagrangian model, MPIC, as well as in the Met Office NERC Cloud model, MONC
Summary
Detailed studies of moist convection continue to play an important role in the development of weather and climate models. Such studies were initially performed using two-dimensional slab-symmetric or axisymmetric models of clouds LES studies form a bedrock of atmospheric research: they have been used to investigate the fine-scale dynamics. Questions around fine-scale mixing remain hard to tackle because of uncertainty about its representation even in LES. Some research questions ask for a Lagrangian perspective: Lagrangian particles can be used in an LES model, but the representation of mixing in the model core is not fully consistent with the way in which particles are treated
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