A facile and reproducible synthetic approach for preparation of core-shell Au-CdS nanocrystals with controllable shell thickness was reported. Due to the difference in band structures between Au and CdS, a pronounced photoinduced charge separation took place at the interface of Au and CdS, resulting in the electron-charged Au core and the hole-enriched CdS shell. The electron-charging of Au core in Au-CdS nanocrystals was revealed with the charge carrier dynamics measurement. An increase in the electron-transfer rate constant was observed for Au-CdS nanocrystals with increasing shell thickness, probably due to the less pronounced electron-hole interaction of thicker CdS that enabled a fuller extent of participation of photoexcited electrons in the charge separation process. On the other hand, the hole-enriched CdS shell of Au-CdS nanocrystals upon light illumination was characterized with a photocatalytic process. The photocatalytic activity of Au-CdS nanocrystals was found to increase with increasing shell thickness, attributable to the greater capability of light absorption achieved by the extensive growth of the CdS shell. The correlation of photocatalytic activity with the shell thickness of Au-CdS nanocrystals corresponded well with that of the electron-transfer rate constant. As compared to the relevant commercial products like N-doped P-25 TiO2 and CdS powders, the as-synthesized Au-CdS nanocrystals exhibited superior photocatalytic performance under visible light illumination, demonstrating their potential as an effective visible-light-driven photocatalyst. To further enhance the durability performance, Zn was introduced into the shell of Au-CdS, producing Au-Cd1-xZnxS nanocrystals that showed relatively high stability in photocatalysis. The present synthetic route can be readily extended to obtain other sulfide-semiconductor-coated Au nanocrystals, such as Au-ZnS, which may find potential use for methanol oxidation in the photoelectrochemical cell.