Low-crystalline or amorphous molybdenum sulfides (MoSx), bearing abundant unsaturated active sites, have been identified as efficient catalysts for electrocatalytic and photocatalytic H-2 evolution reactions, however, their intrinsic activity is still low and need to be further improved for large-scale applications. In this paper, we report that low-crystalline MoSx doped with Co (Co-MoSx) as efficient cocatalysts could be loaded on CdS nanoparticles through a facile and controllable photochemical reduction method and showed high performances in catalyzing H-2 evolution under visible light irradiation (>= 420 nm). The photochemical loading of Co-MoSx was accomplished by using an in-situ formed molecular complex precursor and photogenerated electrons on CdS as reductants under mild conditions. The optimized CdS/Co-MoSx (Co:Mo = 1:4, 2 mol% loading) photocatalyst exhibited a catalytic H-2 evolution rate of 535 mu mol h(-1), which is 1.8 times higher than that of CdS/MoSx, and an apparent quantum efficiency (AQE) of 23.5% was achieved over CdS/Co-MoSx photocatalyst at 420 nm. Co-MoSx catalyst also shows a long-term stability without noticeable activity degradation. Notably, Co-MoSx cocatalyst was found more efficient than that of noble metals in catalyzing photocatalytic H-2 evolution on CdS. The formation of CoMoS phase, the enhanced electrocatalytic activity as well as reduced electron transfer resistance due to the doping effects of Co ions, account for the enhanced catalytic activity of this Co-MoSx cocatalyst. (C) 2017 Elsevier B.V. All rights reserved.