Accurate determination the duration and time of methane migration above the gas hydrate layer is important in better understanding mechanism(s) driving methane migration and its association with climatic change. Difficulty arises from interference by old carbon in methane and sulfur in proper analyzing carbon and oxygen isotopic value rendering the traditional methods such as carbon-14 or planktonic oxygen records untrustworthy. Diffusion model through determination peak concentration of barium sulfate precipitation has been successfully employed to calculate time and length of methane migration in this study. This thesis study barium sulfate peak(s) accumulated in the continental margin sediments in order to understand mechanism(s) controlling methane migration in sediments offshore southwestern Taiwan. Pore water and sediment barium concentrations were analyzed. Barium fluxes were calculated in order to estimate duration of barite accumulation in sediment. Downward sulfate and upward methane flux as well as barium in sediment were also evaluated to better understand authigenic barite precipitation. Results showed that different types of barite peaks existed in our study area, a single barite peak, multiple peaks and no visible barium sulfate peak. The appearances of more than one barite peaks demonstrated that multiple stages of methane vents may have occurred at present and/or in the past at different geological time at sites in our study region. Diffusion model calculation demonstrated that duration of barite accumulation may require about one to eight thousand years. The appearances of both multiple barite peaks as well as no barite peak associated with the present SMTZ in the study area indicated that methane gas venting may not controlled by a single general process such as sea level changes but by the local active tectonic activities.