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Machine-learning-assisted catalytic performance predictions of binary alloy catalysts for glucose hydrogenation

Zhecheng Fang, Sifan Wang, Haoan Fan, Xuezhi Zhao, Huiping Ji, Bolong Li, Zhenyu Zhang, Jianghao Wang, Kaige Wang, Weiyu Song, Reinout Meijboom, Jie Fu

2024Applied Catalysis A General11 citationsDOIOpen Access PDF

Abstract

Sorbitol production involves glucose hydrogenation, which requires co-adsorption of glucose and hydrogen on the catalyst surface for high catalytic performance. Binary alloy catalysts can modulate substrate adsorption to achieve better catalytic performance than Raney Ni. Herein, we established a pioneering DFT/ML approach to investigate the adsorption energies of glucose (ΔE GCHO ) and H atoms (ΔE H ) on 1155 binary alloy catalysts. The Light Gradient Boosting Machine (LGBM) algorithm proved the most effective ML model, predicting ΔE GCHO and ΔE H with R² values of 0.785 and 0.636, respectively. Microkinetic simulation demonstrated a correlation between catalytic activity and adsorption energy, revealing high-performance catalyst screening criteria as ΔE GCHO = −1.45 to −0.65 eV and ΔE H = −0.55–0.00 eV. Nine possible binary alloy catalysts with high predicted activity were identified, with Pd 3 Mg performing best. The present study highlights the potential of the DFT/ML-assisted approach in the development of efficient glucose hydrogenation binary alloy catalysts.

Topics & Concepts

ChemistryCatalysisAlloyBinary numberChemical engineeringOrganic chemistryArithmeticMathematicsEngineeringMachine Learning in Materials ScienceCatalytic Processes in Materials ScienceAsymmetric Hydrogenation and Catalysis