English

Meta-GPT: Decoding the Metasurface Genome with Generative Artificial Intelligence

Optics 2025-12-16 v1 Artificial Intelligence Computation and Language Machine Learning

Abstract

Advancing artificial intelligence for physical sciences requires representations that are both interpretable and compatible with the underlying laws of nature. We introduce METASTRINGS, a symbolic language for photonics that expresses nanostructures as textual sequences encoding materials, geometries, and lattice configurations. Analogous to molecular textual representations in chemistry, METASTRINGS provides a framework connecting human interpretability with computational design by capturing the structural hierarchy of photonic metasurfaces. Building on this representation, we develop Meta-GPT, a foundation transformer model trained on METASTRINGS and finetuned with physics-informed supervised, reinforcement, and chain-of-thought learning. Across various design tasks, the model achieves <3% mean-squared spectral error and maintains >98% syntactic validity, generating diverse metasurface prototypes whose experimentally measured optical responses match their target spectra. These results demonstrate that Meta-GPT can learn the compositional rules of light-matter interactions through METASTRINGS, laying a rigorous foundation for AI-driven photonics and representing an important step toward a metasurface genome project.

Keywords

Cite

@article{arxiv.2512.12888,
  title  = {Meta-GPT: Decoding the Metasurface Genome with Generative Artificial Intelligence},
  author = {David Dang and Stuart Love and Meena Salib and Quynh Dang and Samuel Rothfarb and Mysk Alnatour and Andrew Salij and Hou-Tong Chen and Ho Wai and Lee and Wilton J. M. Kort-Kamp},
  journal= {arXiv preprint arXiv:2512.12888},
  year   = {2025}
}

Comments

Keywords: Physics-informed machine learning; Transformer models; Reinforcement learning; Chain-of-thought reasoning; Metasurfaces; Nanophotonics; Inverse design

R2 v1 2026-07-01T08:24:24.533Z