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Effect of Laves-decorated dendrite structure on hydrogen embrittlement in selective laser-melted nickel-based alloy

Xu Zhao, Yujie Zhu, Saiyu Liu, Weipeng Li, Jiacheng Chen, Kewei Gao, Rongjian Shi, Xiaolu Pang

2025Journal of Material Science and Technology8 citationsDOIOpen Access PDF

Abstract

The effects of the Laves-decorated dendrite structure on the hydrogen-assisted cracking behavior of the SLM-718 alloy were investigated. The Laves phase exhibits a hydrogen desorption activation energy of 47.67 ± 7.85 kJ mol −1 . The results of in situ scanning Kelvin probe force microscopy and hydrogen microprint technique provide direct evidence of the hydrogen trapping by the Laves phase. The high-density dendrite walls consisting of entangled dislocations exhibit an inhibitory effect on hydrogen diffusion. Atomic-scale characterization reveals that dislocation stacking at the Laves/γ-matrix interface induces the formation of dislocation defects and a high-stress concentration in the Laves phase. The presence of hydrogen further promotes the formation of micropore defects and the embrittlement of the Laves phase. Hydrogen-promoted dislocation slip localization and hydrogen-induced reduction of interatomic bonding are the primary reasons for the Laves phase fracture and debonding at the Laves/γ-matrix interface. The coalescence of micropore defects ultimately leads to hydrogen-induced crack formation.

Topics & Concepts

Materials scienceAlloyNickelHydrogen embrittlementMetallurgyEmbrittlementDendrite (mathematics)Laves phaseHydrogenIntermetallicChemistryGeometryCorrosionOrganic chemistryMathematicsAdditive Manufacturing Materials and ProcessesHydrogen embrittlement and corrosion behaviors in metalsWelding Techniques and Residual Stresses
Effect of Laves-decorated dendrite structure on hydrogen embrittlement in selective laser-melted nickel-based alloy | Litcius