The influence of aerosols, serving as cloud condensation nuclei (CCN), on clouds and precipitation becomes a highlighted research topic in recent years due to increasing human activities. Previous studies have suggested that the results of aerosol-cloud-precipitation interaction are regime-dependent. In this study, the regime of interest is focused on the diurnal precipitation over complex topography in Taiwan with weak synoptic-scale weather forcing. Semi-realistic large-eddy simulations (LESs) were carried out using the vector vorticity equation model with high-resolution Taiwan topography (TaiwanVVM) to resolve fine-scale atmospheric processes. The simulations of 13 cases were driven by the simplified observational soundings, selected under weak southwesterly flow or weak synoptic weather events. In the control groups (clean scenarios), the aerosol concentration was fixed at 3×108 kg-1 in the entire domain, while in the experimental groups (normal scenarios), the value was 100 times higher. The composite of the simulated results reveals a precipitation hotspot around Alishan Mountain Range (AMR), which is consistent with the observed climatology. Two different types of precipitation patterns by the AMR regional-averaged rain rate evolution are identified: the STRONG type and the WEAK type. By performing cloud object connecting and rain cell tracking analyses, the properties of cloud and precipitation are examined from the perspective of the life cycle of convection. Several responses due to increasing CCN are highlighted especially for the STRONG type. First, the diurnal precipitating systems with a greater ability to produce heavy rain rates occur more frequently and contribute more to the total precipitation. Also, the initiation and the ending time of the diurnal precipitating systems are delayed. Moreover, the maximum rain rate, rain area, cloud depth, and cloud size become stronger with a more concentrated and vigorous updraft in the clouds during the mature stage of the diurnal precipitating systems. An overall “strong get stronger” response to the diurnal precipitating systems over complex topography is identified with increasing CCN. The relationship between the intensity of local circulation and the precipitation patterns in the AMR region is discussed, with the STRONG type having weaker near-coast low-level southwesterly before the initiation of precipitation. This research shows that semi-realistic LES and tracking of precipitating systems provide novel and useful insights to the understanding of the responses to diurnal precipitation resulting from increasing CCN under relatively weak synoptic weather regime over complex topography.