The number of gas stations in Taiwan increased dramatically after the government lifted the ban on private ownership. However, the gas stations account for a large proportion of the soil and groundwater pollution sites. Leakage from storage tanks and pipelines accounts for the two major sources from which petroleum releases into the subsurface. Air sparging is one of the most commonly adopted in-situ remediation technology to clean up polluted groundwater in gas station sites. Its mechanism is to inject air into underground water where the dissolved constituents partition to vapor phase as they come into contact with the injected air. However, many pollution remediation technologies are difficult to be applied in cases of complicated soil structure. For example, it’s difficult for contaminants to transport within fine-grained soils. This research focuses on two-layered strata, with shallow layer of fined grained soil on top of groundwater table and a layer of sandy soil beneath. A numerical model software called TMVOC is used to simulate air sparging in a model site with the above mentioned geological condition. Four independent variables which controlled the effect of remediation are discussed separately. These variables include, the air injection rate, the vapor extraction rate, the distance between spill point and extraction wells, and the different AS well layout schemes. In addition, the remediation at a model site with homogeneous sandy soil was also as simulated for comparison. The results show that greater air injection rate contributes significantly to efficiency of remediation of aqueous benzene, but increasing air injection rate or vapor extraction rate are less beneficial to removing residual petroleum products in the vadose zone. As SVE well gets closer to the spilling point, the pressure gradient around the contaminants increases, which helps remediate dissolved benzene and total petroleum hydrocarbon (TPH) in practice. The plume expands in the beginning of the air sparging because dissolved constituents are unable to partition to vapor phase in a short time, which happens in all cases. It’s necessary to consider the risk of migrating of contamination during remediation. In all the cases with heterogeneous soil, the vadose zone cannot be cleaned up successfully within reasonable time.