Laser Powder Bed Fusion of high performance nickel-based superalloys is a transformative technology hindered by acute hot-cracking susceptibility and prohibitively expensive process optimization cycles. Traditional data-driven AI models often suffer from "black-box" limitations and severe data scarcity. Here, we propose a knowledge-informed hybrid AI framework that integrates Large Language Models (LLMs) as reasoning agents to bridge metallurgical expertise with autonomous discovery. By operationalizing empirical heuristics (e.g., Al/Ti ratio correlations), the LLM facilitated rapid heuristic pruning, compressing the initial search space of 76 800 candidates by >95%. Subsequently, LLM-distilled process priors were injected into a reinforcement learning (RL) agent, enabling a "warm-start" optimization that achieved safety-constrained exploration in physically risky regimes. The resulting AMN01 alloy achieved crack-free printability with a breakthrough yield strength exceeding 1.5 GPa and an ultimate tensile strength near 1.8 GPa in the direct-aged state. Following solution-aging treatment, the alloy maintained a UTS over 1.6 GPa with an exceptional elongation of over 15%. Multi-scale characterization revealed a multi-tier strengthening architecture involving nanoscale cellular dislocation networks, γ' precipitation, and deformation-induced Lomer-Cottrell locks. This framework establishes a generalizable paradigm for accelerated material discovery in high-cost, data-scarce engineering environments.
Yao et al. (Tue,) studied this question.
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