High potential gas hydrate reservoirs have been proposed in both active and passive margins offshore SW Taiwan. This study analyzes high quality seismic data for understanding the gas hydrate systems in gas hydrate prospects situated in the South China Sea continental slope and the deformation front. From west to east, they are Jiulong Ridge, Horseshoe Ridge, Pointer Ridge, Formosa Ridge and Palm Ridge. 3D seismic data images in Palm Ridge and Pointer Ridge prospects show the detail of the gas hydrate reservoir characters and reveal the relation between the geological processes and gas hydrate systems. Conceptual models of gas hydrate systems are constructed and then gas hydrate systems at different geological settings are compared. To improve the quality and resolution of the 3D seismic images, this study has developed a true 3D seismic data processing technique by utilizing the streamer feathering information from closely spaced 2D seismic profiles. To best extract the information from seismic data, seismic attribute analyses and neural network techniques are applied to enhance the seismic characters of potential reservoirs and fluid conduits in subsurface, such as sandy paleo-channel deposits, faults and chimneys. Three structural domains can be distinguished from seismic profiles that run across the deformation front from west to east in Palm Ridge: the normal fault zone, the proto-thrust zone, and the thrust fault zone. The presence of proto-thrusts that are located west of the frontal thrust implies that the compressional stress field has advanced westward due to the convergence of the Philippine Sea Plate and Eurasian Plate. Since the deformation front is defined as the location of the most frontal contractional structure, no significant contractional structure should appear west of it. We thus suggest moving the location of the previously mapped deformation front farther west to where the westernmost proto-thrust lies. High-resolution seismic and bathymetric data reveal that the directions of the paleo-submarine canyons run transverse to the present slope dip, while the present submarine canyons head down slope in the study area. We propose that this might be the result of westward migration of the deformation front that changed the paleo-bathymetry and thus the canyon path directions. The interactions of down-slope processes and active tectonics control the canyon paths in our study area. In terms of the gas hydrate system in the Palm Ridge prospect, normal faults and thrusts are major conduits for focused fluid flow. Although structural traps and turbidite channel sands are observed in Palm Ridge, none of them can be gas hydrate reservoirs because they all lie below the gas hydrate stability zone (GHSZ). A NE-SW striking normal fault which is called the PR fault acts as a major structure in Pointer Ridge. Sediment wave deposition and canyon erosion features are observed on the hanging wall and the footwall of the PR fault, respectively. Results from seismic attribute analyses show major fluid conduits are the PR fault and the gas chimney features in the footwall of the PR fault. The locations of these fluid conduits correlate well with the gas plume sites observed from water column images, indicating the active fluid flow processes in Pointer Ridge. The chimneys in the hanging wall of the PR fault may not be active conduits for fluid migration since they are all buried by sediments. Paleo-channel cut and fill features indicate that turbidite sands are distributed on both sides of the PR fault. Overall, the most potential gas hydrate reservoirs are the paleo-channel deposits in the footwall of the PR fault which are situated in the GHSZ. Our study results show that the four gas hydrate prospects located on the SCS continental slope have leakage-related structures such as chimneys and normal faults characterized by numerous seepage features, and gas hydrate samples might be recovered on or underneath the seafloor at shallow depth. This study proposes that the Formosa Ridge is the primary gas hydrate sampling site because of its strongest evidences of methane seepages, while the Pointer Ridge as the highest potential site for future gas hydrate development because the turbidite sands could trap significant amount of gases. Based on our observations, gas chimneys are likely to develop in erosion-dominated environments rather than deposition-dominated ones in the South China Sea slope, whereas there is no evidence of gas chimneys in the Palm Ridge area. These phenomena suggest the development of gas chimneys may be controlled by both of tectonic and sedimentary processes.