Effects of tempering temperature on the precipitation behaviors of nanoparticles and their influences on the susceptibility to hydrogen embrittlement of a Cr–Mo–V steel

Abstract

This paper presents an experimental study of tempering treatment to optimize the precipitation behavior of nano-sized particles for improving the resistance to hydrogen embrittlement (HE) of an AISI 4330-type low-alloy high-strength steel. The precipitates and dislocations in the microstructure, which serve as irreversible and reversible hydrogen traps, were quantitatively investigated using TEM, X-ray diffraction and hydrogen permeation techniques. It was found that V-rich M2C precipitates of less than 2 nm size appeared when tempered at 610 °C, a tempering temperature associated with the lowest HE susceptibility of the tempered steel. Furthermore, the hydrogen could promote movement of the multiple dislocation at the low-temperature tempering process but pin the separated dislocation at higher temperature tempering process. The interaction of the dislocations (i.e., multiple dislocation or separated dislocation) with nanoprecipitates and hydrogen atoms produced the hydrogen-induced hardening/softening behavior in a hydrogen-charging environment.