English

Large Language Model Driven Development of Turbulence Models

Fluid Dynamics 2025-12-30 v1

Abstract

Artificial intelligence (AI) has achieved human-level performance in specialized tasks such as Go, image recognition, and protein folding, raising the prospect of an AI singularity-where machines not only match but surpass human reasoning. Here, we demonstrate a step toward this vision in the context of turbulence modeling. By treating a large language model (LLM), DeepSeek-R1, as an equal partner, we establish a closed-loop, iterative workflow in which the LLM proposes, refines, and reasons about near-wall turbulence models under adverse pressure gradients (APGs), system rotation, and surface roughness. Through multiple rounds of interaction involving long-chain reasoning and a priori and a posteriori evaluations, the LLM generates models that not only rediscover established strategies but also synthesize new ones that outperform baseline wall models. Specifically, it recommends incorporating a material derivative to capture history effects in APG flows, modifying the law of the wall to account for system rotation, and developing rough-wall models informed by surface statistics. In contrast to conventional data-driven turbulence modeling-often characterized by human-designed, black-box architectures-the models developed here are physically interpretable and grounded in clear reasoning.

Keywords

Cite

@article{arxiv.2505.01681,
  title  = {Large Language Model Driven Development of Turbulence Models},
  author = {Zhongxin Yang and Yuanwei Bin and Yipeng Shi and Xiang I. A. Yang},
  journal= {arXiv preprint arXiv:2505.01681},
  year   = {2025}
}
R2 v1 2026-06-28T23:19:54.057Z