Abstract
Weather simulations are sensitive to subgrid processes that are parameterized in numerical weather prediction (NWP) models. In this study, we investigated the response of tropical cyclone Idai simulations to different cumulus parameterization schemes using the Weather Research and Forecasting (WRF) model with a 6 km grid length. Seventy-two-hour (00 UTC 13 March to 00 UTC 16 March) simulations were conducted with the New Tiedtke (Tiedtke), New Simplified Arakawa–Schubert (NewSAS), Multi-Scale Kain–Fritsch (MSKF), Grell–Freitas, and the Betts–Miller–Janjic (BMJ) schemes. A simulation for the same event was also conducted with the convection scheme switched off. The twenty-four-hour accumulated rainfall during all three simulated days was generally similar across all six experiments. Larger differences in simulations were found for rainfall events away from the tropical cyclone. When the resolved and convective rainfall are partitioned, it is found that the scale-aware schemes (i.e., Grell–Freitas and MSKF) allow the model to resolve most of the rainfall, while they are less active. Regarding the maximum wind speed, and minimum sea level pressure (MSLP), the scale aware schemes simulate a higher intensity that is similar to the Joint Typhoon Warning Center (JTWC) dataset, however, the timing is more aligned with the Global Forecast System (GFS), which is the model providing initial conditions and time-dependent lateral boundary conditions. Simulations with the convection scheme off were found to be similar to those with the scale-aware schemes. It was found that Tiedtke simulates the location to be farther southwest compared to other schemes, while BMJ simulates the path to be more to the north after landfall. All of the schemes as well as GFS failed to simulate the movement of Idai into Zimbabwe, showing the potential impact of shortcomings on the forcing model. Our study shows that the use of scale aware schemes allows the model to resolve most of the dynamics, resulting in higher weather system intensity in the grey zone. The wrong timing of the peak shows a need to use better performing global models to provide lateral boundary conditions for downscalers.
Highlights
Tropical cyclones are low-pressure systems that develop over warm tropical and subtropical waters [1]
Southeast Africa is impacted by these systems, with Madagascar and Mozambique being the two countries that experience the most damage caused by tropical cyclones which develop in the South West Indian Ocean (SWIO) basin [4,5]
New Simplified Arakawa–Schubert (NewSAS) scheme [51]: The NewSAS is a mass flux scheme based on Pan and Wu [52] with revisions made to the entrainment and detrainment formulation following from large-eddy simulation studies
Summary
Tropical cyclones are low-pressure systems that develop over warm tropical and subtropical waters [1]. There are many cumulus schemes available in the research community, and a number of studies have investigated the sensitivity of different types of events to these schemes, including simulations of tropical cyclones, e.g., [24,25,26]. These climatological studies based on 2, 10, or 30 years of data found that the simulated frequency, intensity, cyclone track, and associated rainfall differ amongst the different convection schemes.
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