Abstract
This study aims to evaluate the potential of selective laser melting (SLM) and laser metal deposition (LMD) for repair of single-crystal nickle-based superalloys, by comparing the morphologies, molten pool characteristics, and microstructural evolution of single tracks of directionally solidified AM900 nickel-based superalloys fabricated via these two laser additive manufacturing techniques. SLM requires linear energy densities above 0.15 J/mm to continuous regular tracks, while LMD achieves them across a broader range. Molten pool morphology transitions from keyhole to spheroidized types, with pools exhibiting optimal grain control corresponding to width-to-depth ratios from 2.8 to 3.3. Both techniques enable [001] epitaxial growth with minimal surface stray grains (∼1–2%), demonstrating SLM's potential for precision repair despite its narrower process window.
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