Hybrid N 2 -CO 2 huff-n-puff (HnP) has been experimentally demonstrated to be a promising approach for improving oil recovery from tight/ultratight shale oil reservoirs. Despite this, the detailed soaking process and interaction mechanisms remain unclear. Adopting molecular dynamic simulations, the soaking behavior of hybrid N 2 -CO 2 HnP was investigated at the molecular and atomic levels. Initially, the soaking process of fluid pressure equilibrium after injection pressure decays in a single matrix nanopore connected to a shale oil reservoir is studied. The study revealed that counter-current and cocurrent displacement processes exist during the CO 2 and hybrid N 2 -CO 2 soaking, but cocurrent displacement occurs much later than counter-current displacement. Although the total displacement efficiency of the hybrid N 2 -CO 2 soaking system is lower than that of the CO 2 soaking system, the cocurrent displacement initiates earlier in the hybrid N 2 -CO 2 soaking system than in the CO 2 soaking system. Moreover, the N 2 soaking process is characterized by only counter-current displacement. Next, the soaking process of fluid pressure nonequilibrium before the injection pressure decays is investigated. It was discovered that counter-current and cocurrent displacement processes initiate simultaneously during the CO 2 , N 2 , and hybrid N 2 -CO 2 soaking process, but cocurrent displacement exerts a dominant influence. During the CO 2 soaking process, many hydrocarbon molecules in the nanopore are dissolved in CO 2 while simultaneously exhibiting a substantial retention effect in the nanopore. After pure N 2 injection, there is a tendency to form a favorable path of N 2 through the oil phase. The injection of hybrid CO 2 -N 2 facilitates the most significant cocurrent displacement effect and the reduction in residual oil retained in the nanopore during the soaking process, thus resulting in the best oil recovery. However, the increase rate in total displacement efficiencies of the different soaking systems over time (especially the hybrid N 2 -CO 2 soaking system) was significantly larger before than after injection pressure decays. Additionally, the displacement effect induced by oil volume swelling is significantly restricted before the injection pressure decays compared to the soaking process after the injection pressure decays. This study explains the role of CO 2 -induced oil swelling and N 2 -induced elastic energy played by hybrid N 2 and CO 2 at different stages of the hybrid N 2 -CO 2 soaking process before and after pressure decays and provides theoretical insights for hybrid gas HnP-enhanced recovery. These pore-scale results highlight the importance of injection pressure and medium composition during the soaking process in unconventional oil reservoirs.