The solution foundation of mesoscopic carbonation is summarized and improved. According to the path dependent feature of transport and reaction， the solution of huge-size matrix in traditional methods is avoided， and a diffusion path dependence mapping （DPDM） method is proposed. Based on the Dijkstra shortest path calculation algorithm， the paths from environmental boundary to any nodes in cement mortar are calculated with the modification of the influence of the interfacial transition zone. With the agent model of cement mortar， the complex coupling process of the hydration reaction， the carbonation reaction， and the change of material properties（concentration of Ca（OH）₂）can be solved. Finally， the solution results of the agent model are mapped on the mesoscopic model with the same length of diffusion path， and the temporal-spatial distribution of critical substance concentration can be accurately and efficiently predicted. The comparison and verification with material test indicate that the simulation results of diffusion path dependence mapping method can accurately simulate the carbonation depth in concrete. Compared with the traditional solution based on partial difference equation， the proposed method can precisely reflect the mesoscopic distribution of critical components， where the solution efficiency can be improved by more than 20 times， and the storage requirement can be reduced to less than 2%.