The purpose of this study focuses on two aspects of hydrogen embrittlement of steels: (1) the effect of microstructural mophology on the hydrogen embrittlement susceptibility of steels produced by different processes; (2) the effect of microalloying addition on the tensile property of steels in the hydrogen environment under the same thermo-mechanical control rolling processing (TMCP) with accelerated cooling. The results show that the ultimate tensile strength and yeild strength of the base metals and weldments of all three steels (TMCP API 5L X65, TMCP EH36,and SM490C) are independent of increasing hydrogen-charging current density. The superior strength and ductility of TMCP API 5L X65 after hydrogen charging can be attributed to the solid solution strengthening and fine precipitates superimposed on the equiaxed refined grains. The relative hard band structures in SM490C steel and weldment are the major cause that renders the lower ultimate tensile strength and elongation inevitable. Under the same composition, the hydrogen diffusivity along the through-surface direction in a banded structure of SM490C steel shows a lower value than that in the equiaxed grain EH36 steel. Whereas, the hydrogen diffusivity and hydrogen permeability of microallyed (Nb, V, Cu, Al, Ni)API 5L X65 steel are lower than that of EH36 steel with no alloying. The reason could be that the API 5L X65 steel formed a protective film enriched Cu arrests hydrogen diffusion.