Precipitation of copper in martensitic steel after tempering is known to trigger secondary hardening effect in quenched-and-tempered (Q&T) martensitic steel. However, there have been few studies conducted to the ability of copper to trap hydrogen in steels. The current work aims at characterizing the effects of copper on hydrogen desorption and resistance to hydrogen embrittlement in Q&T martensitic steels. Moreover, in order to compare with conventional Q&T steel, S690Q offshore steel was also studied. In this research, microstructure was investigated by using optical microscope, scanning electron microscope, and transmission electron microscope. Specimens electrochemically charged with hydrogen was measured in the house-constructed thermal desorption spectroscopy (TDS), and hydrogen desorption models were utilized to analyze experiment results. Resistance to hydrogen embrittlement was finally tested via the notched slow strain rate tensile testing. In conventional Q&T steel, ability to store hydrogen is high in as-quenched steel due to high dislocation density and grain boundary and it will degrade after tempering. Cementite particles, formed by tempering in conventional Q&T steel, have weak ability to trap hydrogen. However, precipitation of copper can enhance the hydrogen trapping in the copper-containing Q&T steel. Based on the analyses by Kissinger method and McNabb-Foster method, the binding energy of copper particle was estimated to be 35 to 40 kJ/mol. Strong enhancement in hydrogen trapping was observed when the steel was tempered at 540 oC or 600 oC. This is consistent with the fact that high-density copper particles were also observed in steels under these tempering conditions. In SSRT tests, steel with copper precipitation shows better resistance to hydrogen embrittlement. In conclusion, precipitation of copper is a metallurgical approach in designing a strong and tough Q&T steel with high resistance to hydrogen embrittlement.