In the western plains of Taiwan, there are several rapid rivers that originate from the mountainous terrain. Turbulent flow transports large quantities of river sedimentation that accumulate in the riverbed downstream. River dust episodes are extreme dust events occasionally generated from the dry riverbeds. Choushui and Kaoping rivers are considered to be the two rivers with the highest potential for river dust events in central and southern Taiwan, respectively. When the monsoon prevails, the accumulated river sedimentation in the estuary can easily be lifted into the air. Due to this, vulnerable populations living near riverbanks are exposed to high PM10 concentrations, which may have adverse health effects. The spatial-temporal distribution of river dust episodes is first analyzed through a simple statistical analysis. It has been determined that river dust events will be prevalent along the Choushui river from October to April next year, while along the Kaoping river from March to September. Furthermore, a correlation analysis is conducted to examine the relationship between river dust ( PM10 ) and relevant hydro-meteorological factors (i.e., temperature, precipitation, relative humidity, and wind speed). However, natural signals are nonlinear, nonstationary, and multiscale, which limits the possibility of determining a correlation between the two factors using traditional time frequency analysis (for example, the Fourier transform and wavelet transform). As a result, we introduce a time-dependent intrinsic correlation (TDIC) based on the Improved Complete Ensemble Empirical Mode Decomposition with Adaptive Noise (ICEEMDAN) algorithm. Based on the ICEEMDAN algorithm, the annual and diurnal scales are identified to be significant among the PM10 and relevant hydro meteorological factors. Only the wind speed at the Lunbei station showed a positive correlation at the annual scale, whereas other factors showed a strong negative correlation. A seasonal switchover of correlation can be observed between PM10 and temperature, relative humidity, and wind speed at the diurnal scale. The positive correlations are attributed to the season of river dust episodes in the Choushui and Kaoping rivers. A scale-dependent wind motion analysis based on the ICEEMDAN algorithm is also presented to examine how wind patterns affect PM10 concentrations and river dust episodes. On a diurnal scale, PM10 concentration is related to land-sea breezes, while on an annual scale, it corresponds to the winter monsoon. The river dust episodes are associated with the northeast monsoon along the Choushui river, while they occur along the Kaoping river both during the northwest and southwest monsoons. In order to reduce significant health risks associated with river dust episodes, a hybrid Improved Complete Ensemble Empirical Mode Decomposition with Adaptive Noise - Radial Basis Function Neural Network (ICEEMDAN-RBFNN) prediction model is proposed. A comparison is made between the hybrid model and the RBFNN and Multilayer Perceptron (MLP) models for forecasting future three-hour PM10 concentrations. For network modeling, temperatures, relative humidity, wind speeds, wind direction indexes, and previous hours of PM10 concentrations are taken into account. The results showed the accuracy of the hybrid model outperformed the RBFNN and the MLP models in capturing either the high or low PM10 concentrations for the next three hours. Accordingly, it is evident that the hybrid ICEEMDAN-RBFNN model is capable of predicting PM10 efficiently, serving as an early warning system for episodes of river dust. In addition, the stability of the proposed hybrid model can be proven by the changed length of the input previous PM10 concentrations. Finally, risk assessments are shown as an application of the proposed hybrid model in this study.