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In-situ TiC particle-reinforced Hastelloy X superalloy fabricated by laser additive manufacturing

Chen Wang, Yang Li, Ruixin Sheng, Shuai Guan, Zhongnan Bi, Hua Zhang, Hailiang Huang, Liang Jiang, Liwen Zhu, Xin Zhou

2025Journal of Materials Research and Technology27 citationsDOIOpen Access PDF

Abstract

In-situ metal matrix composites are desirable for achieving optimum mechanical properties. This study investigated the enhancement of mechanical performance in Hastelloy X (HX) superalloy through in-situ synthesis of TiC and γ′ phases via titanium (Ti) addition using a high-throughput laser additive manufacturing system. The influence of Ti content on phase evolution, microstructure, and mechanical properties was comprehensively analyzed for both the as-deposited and heat-treated HX superalloys. The results revealed that increasing Ti content exacerbated micro-segregation during the deposition, promoting pronounced dendritic growth and a higher σ phase volume fraction. These microstructural changes enhanced tensile strength while concurrently elevated cracking susceptibility, with macroscopic cracking detected upon reaching 5 wt% Ti. Following heat treatment, micro-segregation was significantly reduced. In alloys containing 2–4 wt% Ti, TiC and nano-sized γ′ phases precipitated after heat treatment, leading to a 40 % improvement in yield strength and tensile strength compared to the baseline HX superalloy, while maintaining an elongation of approximately 30 %.

Topics & Concepts

Materials scienceSuperalloyMetallurgyIn situParticle (ecology)LaserAlloyOpticsGeologyPhysicsMeteorologyOceanographyAdditive Manufacturing Materials and ProcessesHigh Entropy Alloys StudiesAdditive Manufacturing and 3D Printing Technologies
In-situ TiC particle-reinforced Hastelloy X superalloy fabricated by laser additive manufacturing | Litcius