Abstract

The nature of rapid cyclic heating and cooling in metal additive manufacturing poses a great challenge in the control of microstructure while a metallic part is being built. With metastable α′ martensites commonly present in a columnar prior-β grain structure, Ti-6Al-4V alloy made by laser powder-bed fusion additive manufacturing ( L -PBF AM) is strong but often suffers from anisotropic mechanical behavior, inferior ductility and low fracture toughness. This drives the recent development in L -PBF process optimisation to produce ultrafine lamellar α + β microstructures directly in the as-built state of Ti-6Al-4V. Currently, in-situ martensite decomposition is deemed as the transformation pathway responsible for the formation of such lamellar microstructures. However, without solid experimental evidence this consensus cannot be reached and is still in question. Here we show that, instead of martensite decomposition, a pathway of slow cooling from the β phase field at much reduced cooling rates (below 5 °C s −1 ) is proven to give rise to the observed lamellar α + β microstructure. This is underpinned by several microstructural “fingerprints” such as grain-boundary α (GB-α), α colony and α lath width, and crystallographic orientations of the constituent phases. The finding deepens our established wisdom in L -PBF AM and opens a new avenue for microstructural control in metal additive manufacturing. • Thermal history in laser additive manufacturing of Ti-6Al-4V was elaborated via quantitative microstructural interpretation. • Two transformation pathways were compared to uncover the mechanism responsible for the lamellar microstructure formation. • The formation kinetics of the lamellar α + β in the as-built state of Ti-6Al-4V was interpreted using TTT/CCT diagrams.

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