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Hauptverfasser: Huang, Wenqiang, Fang, Susu, Gu, Xuhang, Xue, Shen'ao, Xing, Huanhuan, Jiang, Junjie, Zhang, Junying, Zhou, Shen, Luo, Zheng, Zhang, Jin, Ouyang, Fangping, Wang, Shanshan
Format: Preprint
Veröffentlicht: 2026
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Online-Zugang:https://arxiv.org/abs/2603.16959
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author Huang, Wenqiang
Fang, Susu
Gu, Xuhang
Xue, Shen'ao
Xing, Huanhuan
Jiang, Junjie
Zhang, Junying
Zhou, Shen
Luo, Zheng
Zhang, Jin
Ouyang, Fangping
Wang, Shanshan
author_facet Huang, Wenqiang
Fang, Susu
Gu, Xuhang
Xue, Shen'ao
Xing, Huanhuan
Jiang, Junjie
Zhang, Junying
Zhou, Shen
Luo, Zheng
Zhang, Jin
Ouyang, Fangping
Wang, Shanshan
contents Exemplified by the chemical vapor deposition growth of two-dimensional dendrites, which has potential applications in catalysis and presents a parameter-intensive, data-scarce and reaction process-complex model problem, we devise a machine intelligence-empowered framework for the full chain support of material synthesis, encompassing rapid process optimization, accurate customized synthesis, and comprehensive mechanism deciphering.First, active learning is integrated into the experimental workflow, identifying an optimal recipe for the growth of highly-branched, electrocatalytically-active ReSe2 dendrites through 60 experiments (4 iterations), which account for less than 1.3% of the numerous possible parameter combinations.Then, a prediction accuracy-guided data augmentation strategy is developed combined with a tree-based machine learning (ML) algorithm, unveiling a non-linear correlation between 5 process variables and fractal dimension (DF) of ReSe2 dendrites with only 9 experiment additions, which guides the synthesis of various user-defined DF. Finally, we construct a data-knowledge dual-driven mechanism model by integration of cross-scale characterizations, interpretable ML models, and domain knowledge in thermodynamics and kinetics, unraveling synergistic contributions of multiple process parameters to the product morphology. This work demonstrates the ML potential to transform the research paradigm and is adaptable to broader material synthesis.
format Preprint
id arxiv_https___arxiv_org_abs_2603_16959
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Machine intelligence supports the full chain of 2D dendrite synthesis
Huang, Wenqiang
Fang, Susu
Gu, Xuhang
Xue, Shen'ao
Xing, Huanhuan
Jiang, Junjie
Zhang, Junying
Zhou, Shen
Luo, Zheng
Zhang, Jin
Ouyang, Fangping
Wang, Shanshan
Materials Science
Artificial Intelligence
Exemplified by the chemical vapor deposition growth of two-dimensional dendrites, which has potential applications in catalysis and presents a parameter-intensive, data-scarce and reaction process-complex model problem, we devise a machine intelligence-empowered framework for the full chain support of material synthesis, encompassing rapid process optimization, accurate customized synthesis, and comprehensive mechanism deciphering.First, active learning is integrated into the experimental workflow, identifying an optimal recipe for the growth of highly-branched, electrocatalytically-active ReSe2 dendrites through 60 experiments (4 iterations), which account for less than 1.3% of the numerous possible parameter combinations.Then, a prediction accuracy-guided data augmentation strategy is developed combined with a tree-based machine learning (ML) algorithm, unveiling a non-linear correlation between 5 process variables and fractal dimension (DF) of ReSe2 dendrites with only 9 experiment additions, which guides the synthesis of various user-defined DF. Finally, we construct a data-knowledge dual-driven mechanism model by integration of cross-scale characterizations, interpretable ML models, and domain knowledge in thermodynamics and kinetics, unraveling synergistic contributions of multiple process parameters to the product morphology. This work demonstrates the ML potential to transform the research paradigm and is adaptable to broader material synthesis.
title Machine intelligence supports the full chain of 2D dendrite synthesis
topic Materials Science
Artificial Intelligence
url https://arxiv.org/abs/2603.16959