Effect of the Initial Vortex Size on Intensity Change in the WRF‐ROMS Coupled Model

Numerous studies have demonstrated that the tropical cyclone (TC) induced sea surface temperature (SST) cooling strongly depends on the preexisting oceanic condition and TC characteristics. However, very few focused on the correlation of SST cooling and the subsequent intensity with TC size. Therefore, a series of idealized numerical experiments are conducted using the Weather Research Forecasting (WRF) model coupled with the Regional Ocean Model System (ROMS) model to understand how the vortex size is related to SST cooling and subsequent intensity changes of a stationary TC‐like vortex. In the uncoupled experiments, the radius of maximum wind (RMW) and size (radius of gale‐force wind (R17)) both depend on the initial size within the 72 h simulation. The initially small vortex is smaller than the medium and large vortices throughout its life cycle and is the weakest. In other words, thermodynamic processes do not contribute as much to the R17 change as the dynamic processes proposed (e.g., angular momentum transport) in previous studies. In the coupled experiments, the area‐averaged SST cooling induced by medium and large TCs within the inner‐core region is comparable due to the similar surface winds and thus mixing in the ocean. Although a stronger SST cooling averaged within a larger region outside the inner‐core is induced by the larger TC, the intensity of the larger TC is more intense. This is because that the enthalpy flux in the inner‐core region is higher in the larger TC than that in the medium and small TCs.