This work aims to develop offshore low carbon martensitic steel with hydrogen embrittlement resistance. Nano-precipitation, that trigger secondary hardening effect in quenched-and-tempered (Q T) martensitic steel, act as hydrogen trapping sites in steels that deters hydrogen diffusion. The first work aims to characterize hydrogen desorption capability and resistance to hydrogen embrittlement in copper contained Q T martensitic steels. Microstructure was investigated by scanning electron microscope, transmission electron microscope, and atom probe tomography. Hydrogen was electrochemically charged and hydrogen desorption was measured by the house-constructed thermal desorption analyzer. Resistance to hydrogen embrittlement was finally tested via the notched slow strain rate tensile test (SSRT). It’s found that copper precipitation can enhance the hydrogen trapping in Q T steel. The activation energy of ε-copper as hydrogen trapping site was estimated as 30-35 kJ mol-1 by Kissinger formula and Choo Lee method. In SSRT tests, ε-copper contained steel shows better resistance to hydrogen embrittlement. The result validates ε-copper can act as benign hydrogen trapping site that deters hydrogen embrittlement in steels. By inheriting the idea that nano-precipitation can act as benign hydrogen trapping site, steels with two kinds of nano-precipitation was manufactured and introduced by designed heat treatment. In sequence precipitation, oval TiC carbide was the legacy of austenization process, while ε-copper was introduced by tempering. It is found that ε-copper was the major hydrogen trapping site and oval TiC does not show strong hydrogen trapping capability under room temperature. On the other hand, in co-precipitation heat treatment, ε-copper and TiC carbide was both introduced by tempering. Co-precipitated copper precipitate and platelet TiC carbides shows a strong hydrogen trapping capability with a series of hydrogen trapping activation energy. The excess hydrogen content was purposed to be introduced by size limitation by each precipitates, and lattice imperfection by tetragonality between precipitates. The idea of co-precipitation was accepted and adopted into modern industrialized manufacturing process by implementing direct quenching and tempering process with proper alloying composition. This work finally developed industrial favored co-precipitated DQ T martensitic steel with hydrogen embrittlement resistance.