It is well known that steels are susceptible to hydrogen degradation and corrosion damage in wet sulfide environments. Approachs employed by researchers to minimize the hydrogen embrittlement problem include materials selection, design, inhibition, surface modificaton and control of the microstructure. Currently, inhibitors are extensivly used for various types of corrosion, but the use of inhibitor is an undeveloped control technique for hydrogen embrittlement. In this study, electrochemical hydrogen permeation technique was used to evaluate the effect of the addition of sixteen chemical additives on hydrogen absorption in steel to improve the hydrogen embrittlement resistance. A corrosion measurement was also performed to search an effective inhibitor for both corrosion control and hydrogen degradation in wet sulfide encironment. The permeation results show that addition of Fe(superscript 3+), Fe(superscript 2+), Cu(superscript 2+), Zn(superscript 2+) and Ni(superscript 2+)ions to wet sulfide environments are benefit for hydrogen embrittlement resistance of steel, but Fe(superscript 3+), Cu(superscript 2+) and Ni(superscript 2+) ions may cause the accelerated corrosion of steel. Hydrogen permeation data are slightly affected by addition of Mn(superscript 2+), Mg(superscript 2+), Ca(superscript 2+), Cl(superscript -), SO(superscript 2-)4 and S2O(superscript 2-)3 ions.V2O5 exhibits a hydrogen poison effect for steel. CrO(superscript 2-)4, MoO(superscript 2-)4 and thiourea are corrosion inhibitors, also show cathodic poison effect.