English

MSP-LLM: A Unified Large Language Model Framework for Complete Material Synthesis Planning

Artificial Intelligence 2026-03-03 v3 Materials Science

Abstract

Material synthesis planning (MSP) remains a fundamental and underexplored bottleneck in AI-driven materials discovery, as it requires not only identifying suitable precursor materials but also designing coherent sequences of synthesis operations to realize a target material. Although several AI-based approaches have been proposed to address isolated subtasks of MSP, a unified methodology for solving the entire MSP task has yet to be established. We propose MSP-LLM, a unified LLM-based framework that formulates MSP as a structured process composed of two constituent subproblems: precursor prediction (PP) and synthesis operation prediction (SOP). Our approach introduces a discrete material class as an intermediate decision variable that organizes both tasks into a chemically consistent decision chain. For SOP, we further incorporate hierarchical precursor types as synthesis-relevant inductive biases and employ an explicit conditioning strategy that preserves precursor-related information in the autoregressive decoding state. Extensive experiments show that MSP-LLM consistently outperforms existing methods on both PP and SOP, as well as on the complete MSP task, demonstrating an effective and scalable framework for MSP that can accelerate real-world materials discovery.

Keywords

Cite

@article{arxiv.2602.07543,
  title  = {MSP-LLM: A Unified Large Language Model Framework for Complete Material Synthesis Planning},
  author = {Heewoong Noh and Gyoung S. Na and Namkyeong Lee and Chanyoung Park},
  journal= {arXiv preprint arXiv:2602.07543},
  year   = {2026}
}
R2 v1 2026-07-01T10:25:56.912Z