This study intends to verify the hypothesized recondensation-induced nucleation (RIN) mechanism, which was proposed by Chen (1999) to explain several observed inconsistencies between the diurnal variations in the aerosol number and mass concentrations over urban areas. Essentially, the core concept of the RIN mechanism is that the combustion process of an internal combustion engine not only acts as a source of aerosol particles but also converts pre-existing aerosol particles into smaller and more numerous ones while obeying total aerosol mass conservation. This study investigates the RIN mechanism through constructing a simple box model as well as implementing a comprehensive parameterization scheme into the aerosol module of the Community Multi-Scale Air Quality (CMAQ) model for simulations. In the process, a systematic method is developed as a byproduct to prepare the model-ready emission fields from several data sources. The box model results reveal that the aerosol number and surface area are the key aerosol physical properties particularly sensitive to the effects of the RIN mechanism but the aerosol volume is not. To analyze further into the details, a summer case on 2015 July 15th over Taiwan is selected for CMAQ model simulations. The results show that at places where the RIN mechanism is the most active such as major cities and highways, the overall aerosol number concentration can increase up to 400% while the overall aerosol surface area concentration can increase up to 20%. The overall aerosol mass concentration shows weak but clear increases up to 2%, a result seemingly contradictory to the mass conservation principle but in fact due to the feedback from complex aerosol dynamics. The model simulations demonstrate that the changes induced by the RIN mechanism in the aerosol physical properties may lead to potential health risks and visibility degradation. Future particle emission standards for internal combustion engines may need to be re-evaluated.