It is well known that some diseases are caused by fine particulate matters such as PM2.5. Therefore, the forecast of such particles gains an increasing public concern. Due to the uncertainty of the dynamic formulation process of the tiny particles (emission data and their projections), modelling PM2.5 concentrations remains a challenging task. Since PM2.5 forecasting is a complex non-linear problem, artificial neural networks (ANNs) are often used in previous studies. The hybrid model (CNN-BP), which is a fusion of the Convolutional Neural Network (CNN) and a Back Propagation Neural Network (BPNN), is proposed in this study to make accurate PM2.5 forecasts for multiple stations at multiple horizons simultaneously through effectively learning the dominant features of input data. The datasets used for the PM2.5 forecasting in this study are related to six air quality and two meteorological factors (hourly) collected from 73 air quality monitoring stations in Taiwan during 2017. The hourly monitoring datasets (639,480) were allocated into training (409,238, 64%), validation (102,346, 16%), and testing (127,896, 20%) stages. The results demonstrate this proposed CNN-BP model can produce more accurate regional multi-step-ahead PM2.5 forecasts (73 stations; t+1−t+10), as compared to the widely used ANNs like BPNN, random forest and long short term memory neural network. With the ability to handle the heterogeneous inputs (with relatively large time-lags) adequately, the CNN-BP can mitigate the loss caused by dimension reduction. In addition, this hybrid model can explore the differences in PM2.5 mechanisms (local emission and transboundary transmission) for the 5 regions (R1-R5) and the whole Taiwan. In this study, exactly one model (i.e. the proposed CNN-BP model) is used to make multi-site (regional) and multi-horizon forecasting, which is a novel achievement. Consequently, this work suggests a real-time PM2.5 forecast service for the public.