TY - GEN
T1 - Simulating Spectroscopy Measuring Processes and Results Using Large Language Models
AU - Ren, Gongxizi
N1 - Publisher Copyright:
© 2025 IEEE.
PY - 2025/11/28
Y1 - 2025/11/28
N2 - Large language models (LLMs) have recently demonstrated remarkable potential in participating scientific research; however, their reliance on statistical learning limits the ability to perform physically consistent reasoning. To address this challenge, an LLM-Spec framework is presented in this research as an end-to-end tool for experimental planning and result prediction in materials characterization using spectroscopy techniques. LLM-Spec is an LLM-based framework that integrates GPT-4 with established physics, chemistry, and spectroscopy databases and first-principles density functional theory (DFT) simulations. The framework decomposes spectroscopy measurements into four embedded modules, including technique selection, sample preparation, experimental workflow design, and DFT-based spectral prediction. Each module is grounded in structured, physics-informed reasoning logic. By coupling semantic reasoning with physically validated databases and computational models, LLM-Spec transforms qualitative scientific intent into quantitatively verifiable experimental plans and simulation outputs. This integration ensures logical coherence across the spectroscopy measuring process and establishes a scalable paradigm for applying LLMs to data-driven, physically interpretable research in materials science.
AB - Large language models (LLMs) have recently demonstrated remarkable potential in participating scientific research; however, their reliance on statistical learning limits the ability to perform physically consistent reasoning. To address this challenge, an LLM-Spec framework is presented in this research as an end-to-end tool for experimental planning and result prediction in materials characterization using spectroscopy techniques. LLM-Spec is an LLM-based framework that integrates GPT-4 with established physics, chemistry, and spectroscopy databases and first-principles density functional theory (DFT) simulations. The framework decomposes spectroscopy measurements into four embedded modules, including technique selection, sample preparation, experimental workflow design, and DFT-based spectral prediction. Each module is grounded in structured, physics-informed reasoning logic. By coupling semantic reasoning with physically validated databases and computational models, LLM-Spec transforms qualitative scientific intent into quantitatively verifiable experimental plans and simulation outputs. This integration ensures logical coherence across the spectroscopy measuring process and establishes a scalable paradigm for applying LLMs to data-driven, physically interpretable research in materials science.
KW - density functional theory simulation
KW - large language models
KW - materials characterization
KW - spectroscopy experiment protocol
UR - https://www.scopus.com/pages/publications/105035995227
U2 - 10.1109/aihcir67580.2025.11405289
DO - 10.1109/aihcir67580.2025.11405289
M3 - Conference Proceeding (ISBN)
T3 - International Conference on Artificial Intelligence, Human-Computer Interaction and Robotics
BT - 2025 4th International Conference on Artificial Intelligence, Human-Computer Interaction and Robotics, AIHCIR 2025
PB - Institute of Electrical and Electronics Engineers
T2 - 2025 4th International Conference on Artificial Intelligence, Human-Computer Interaction and Robotics, AIHCIR 2025
Y2 - 28 November 2025 through 30 November 2025
ER -