Guardado en:
Detalles Bibliográficos
Autores principales: Li, Yanjie, Xu, Jian, Zhang, Xu-Yao, Xiang, Shiming, Ran, Nian, Li, Weijun, Liu, Cheng-Lin
Formato: Preprint
Publicado: 2026
Materias:
Acceso en línea:https://arxiv.org/abs/2605.17254
Etiquetas: Agregar Etiqueta
Sin Etiquetas, Sea el primero en etiquetar este registro!
_version_ 1866913151892586496
author Li, Yanjie
Xu, Jian
Zhang, Xu-Yao
Xiang, Shiming
Ran, Nian
Li, Weijun
Liu, Cheng-Lin
author_facet Li, Yanjie
Xu, Jian
Zhang, Xu-Yao
Xiang, Shiming
Ran, Nian
Li, Weijun
Liu, Cheng-Lin
contents Property prediction and inverse structural design of catalytic materials are typically modeled as two independent tasks: the former predicts target properties from given structures, whereas the latter generates candidate structures according to desired properties. Although the decoupled paradigm facilitates the implementation of a ``generation--evaluation--screening'' workflow, the inconsistency between the generative model and the property prediction model in terms of representation spaces and training objectives can readily introduce data distribution shifts and evaluator bias, thereby limiting the stability of closed-loop optimization. In this work, we propose QE-Catalytic-V2, a unified graph--text multimodal large language model for catalytic materials, which integrates property prediction and inverse design within the same model and shared representation space. Under this unified framework, QE-Catalytic-V2 can not only perform reliable property prediction by leveraging three-dimensional structures and textual information, but also generate and screen physically feasible CIF candidates conditioned on target properties, thereby forming a closed-loop optimization workflow of ``inverse design--prediction--screening--redesign.'' Experimental results demonstrate that this unified paradigm outperforms decoupled baselines on both catalytic relaxed-energy prediction and inverse design tasks, validating the effectiveness of jointly modeling property prediction and structure generation within a single multimodal model.
format Preprint
id arxiv_https___arxiv_org_abs_2605_17254
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle CatalyticMLLM: A Graph-Text Multimodal Large Language Model for Catalytic Materials
Li, Yanjie
Xu, Jian
Zhang, Xu-Yao
Xiang, Shiming
Ran, Nian
Li, Weijun
Liu, Cheng-Lin
Artificial Intelligence
Property prediction and inverse structural design of catalytic materials are typically modeled as two independent tasks: the former predicts target properties from given structures, whereas the latter generates candidate structures according to desired properties. Although the decoupled paradigm facilitates the implementation of a ``generation--evaluation--screening'' workflow, the inconsistency between the generative model and the property prediction model in terms of representation spaces and training objectives can readily introduce data distribution shifts and evaluator bias, thereby limiting the stability of closed-loop optimization. In this work, we propose QE-Catalytic-V2, a unified graph--text multimodal large language model for catalytic materials, which integrates property prediction and inverse design within the same model and shared representation space. Under this unified framework, QE-Catalytic-V2 can not only perform reliable property prediction by leveraging three-dimensional structures and textual information, but also generate and screen physically feasible CIF candidates conditioned on target properties, thereby forming a closed-loop optimization workflow of ``inverse design--prediction--screening--redesign.'' Experimental results demonstrate that this unified paradigm outperforms decoupled baselines on both catalytic relaxed-energy prediction and inverse design tasks, validating the effectiveness of jointly modeling property prediction and structure generation within a single multimodal model.
title CatalyticMLLM: A Graph-Text Multimodal Large Language Model for Catalytic Materials
topic Artificial Intelligence
url https://arxiv.org/abs/2605.17254