The interfacial interaction between rubber-modified asphalt and aggregate has an important connection with the durability and high-temperature stability of asphalt pavements. The microscopic knowledge of this interfacial interaction is not comprehensive in the existing studies. Based on the molecular dynamics simulation, taking Materials Studio software as the research tool, an interfacial model consisting of matrix asphalt, natural rubber asphalt, butadiene rubber asphalt, styrene butadiene rubber asphalt (15% admixture) and four mineral components (quartz, calcite, sodium feldspar, microplagioclase feldspar) in a two-by-two composition is built to explore the diffusion behavior of different asphalt components on the surface of the four aggregates from the molecular scale and to analyze the influence law of different rubber types on the diffusion effects. The results show that the diffusion of light components on the aggregate surface is stronger than that of heavy components, and the molecular weight plays a key role in the diffusion rate of asphalt components. On the surface of different aggregates, the addition of rubber molecular chains has a positive effect on enhancing the diffusion coefficient of asphalt components, and the action pattern of different types of rubber is different. The research result can provide a reference basis for the preparation of suitable rubber-modified asphalt for different mineral types.