The Roles of Chaos Seeding and Multiple Perturbations in Convection-Permitting Ensemble Forecasting over Southern China

Abstract

Abstract The roles of chaos seeding and multiple perturbations, including model perturbations and topographic perturbations, in convection-permitting ensemble forecasting, are assessed. Six comparison experiments were conducted for 14 heavy rainfall events over southern China. Chaos seeding was run as a benchmark experiment to compare their effects to the intended perturbations. The results first reveal the chaos seeding phenomenon. That is, the tiny and local perturbations of the skin soil moisture propagate into the whole analysis domain within an hour and expand to every prognostic variable, and the perturbations derived from chaos seeding develop when moist convection is active. Second, the chaos seeding has a statistically significant difference from our intended perturbations for the ensemble spread magnitudes of precipitation and the spread–skill relationships and probabilistic forecast skills of dynamical variables. Additionally, for the probabilistic forecasts of precipitation, initial and lateral boundary perturbations and model perturbations can yield statistically larger FSS and AROC scores than chaos seeding; topographic perturbations can only improve FSS and AROC scores a little. The different performances may be related to the different degrees of the real dynamical influence of our intended perturbations. Finally, model perturbations can increase the ensemble spreads of precipitation, and improve FSS and AROC scores of precipitation and the consistency of mid- and low-level dynamical variables. However, the effects of topographic perturbations are small.