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The appropriate selection of CO 2 –N 2 mixed gas is critical for cost-effective and efficient gas flooding in enhanced oil recovery. Optimizing this process requires a molecular-level understanding of the interfacial mass transfer mechanisms and their governing factors. This study employs molecular dynamics simulations to reinvestigate the classical surface renewal theory from a molecular perspective, developing a quantitative characterization method for the renewal frequency of surface voids, and to elucidate the underlying micro-mechanisms of interfacial mass transfer. It was found that the renewal frequency of surface voids serves as the dominant factor influencing mass transfer, governed by the competition between the gas–oil interaction and the oil–oil interaction. The crude oil extraction efficiency improves with a higher CO 2 molar fraction in the mixed gas. A critical molar fraction (CMF) of CO 2 was identified for different alkane systems, beyond which the mass transfer performance enhances significantly. Crude oils with heavier components are associated with higher CMF values. These results are attributed to the higher molecular density and stronger gas–oil interactions in CO 2 -rich mixed gases. Therefore, optimizing the CO 2 –N 2 mixed gases with a CO 2 fraction above the system-specific CMF can achieve high mass transfer efficiency while enhancing economic feasibility by reducing reliance on pure CO 2 with high economic costs, providing a foundation and molecular-scale insights for designing gas injection processes.