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In situ dissolution–reprecipitation of TiC in SLM-fabricated functionally graded 316L/TiC composites: microstructural evidence and strengthening mechanisms

Elina Akbarzadeh Chiniforoush, S. Yazdani, Mohammad Reza Jandaghi, Johan Moverare

2025Materials & Design11 citationsDOIOpen Access PDF

Abstract

• In-situ dissolution–reprecipitation of TiC revealed in SLM 316L/TiC composites. • Particle-size-driven transition from columnar to equiaxed grain morphology. • Dual TiC role: heterogeneous nucleation and load transfer strengthening. • Marangoni convection controls secondary TiC particle segregation patterns. • Highest strength in fine-TiC layer via grain refinement and nanoparticle pinning. This study provides the first direct multimodal evidence of dissolution and reprecipitation of TiC during selective laser melting (SLM) of 316L/TiC composites. Functionally graded samples were fabricated with a three-layer architecture: pure 316L SS (L1), 316L + 10 wt% fine TiC (L2), and 316L + 10 wt% coarse TiC (L3). Defect-free samples thereby enabled an isolated study of the particle-size effects on solidification, phase evolution, and strengthening mechanisms. EBSD revealed a transition from coarse columnar grains in L1 to fully equiaxed grains in L2, driven by TiC-induced heterogeneous nucleation and Zener pinning. High-resolution SEM, XRD, and EDS confirmed two distinct populations of secondary TiC: fragmentation-derived intragranular particles (∼100–300 nm) and nanoscale intergranular precipitates formed via dissolution–reprecipitation. Fine TiC reinforcement yielded the most refined microstructure, with the highest high-angle grain boundary fraction (96.6 %). Fine-TiC composites achieved the highest yield strength (847 ± 18 MPa) and ultimate tensile strength (1042 ± 10 MPa), representing ∼ 90 % and ∼ 62 % improvements over pure 316L, respectively, with reduced ductility. Strengthening arose from grain refinement (Hall–Petch), Orowan looping, and load transfer. These results clarify the particle-size-dependent mechanisms governing microstructure–property relationships in SLM-fabricated metal-matrix-composites (MMCs) and offer guidelines for reinforcement engineering.

Topics & Concepts

Materials scienceEquiaxed crystalsGrain boundaryNucleationUltimate tensile strengthComposite materialMetallurgyElectron backscatter diffractionStrengthening mechanisms of materialsGrain boundary strengtheningIntergranular corrosionPhase (matter)Marangoni effectNanoscopic scaleCrystalliteGrain sizeMicrostructureSuperalloyVolume fractionDissolutionTexture (cosmology)NanoparticlePorosityParticle (ecology)Dynamic recrystallizationCeramicEutectic systemAdvanced materials and compositesAluminum Alloys Composites PropertiesMetal and Thin Film Mechanics
In situ dissolution–reprecipitation of TiC in SLM-fabricated functionally graded 316L/TiC composites: microstructural evidence and strengthening mechanisms | Litcius