Insights into Structure-Activity Relationships between Y Zeolites and their n-C10 Hydrocracking Performances via Machine Learning Approaches

doi:10.1016/S1872-2067(24)60259-7

Abstract

Abstract:

Hydrocracking technology represents a crucial position in the conversion of heavy oil and the transformation development from oil refining to the chemical industry. The properties of catalysts are one of the key factors in the hydrocracking process. As the main acidic component of hydrocracking catalyst, the influence of zeolite properties on the reaction performance has been the focus of research. In this study, a series of NiMo/Al₂O₃-Y catalysts were prepared using different Y zeolites as acidic components, and their performances in the hydrocracking of n-C₁₀ were also evaluated. The structure-activity relationship between Y zeolite and the cracking performance of n-C₁₀ was investigated with machine learning. First, a database of the physical and chemical properties of Y zeolite and their performance was established, and the correlation analysis was also conducted. Parameters such as the cell constant, acid content, acid strength, B/L ratio, mesopore volume, micropore volume of Y zeolite, and the reaction temperature were selected as independent variables. The conversion of n-C₁₀ and the ratios of products C₃/C₇ and i-C₄/n-C₄ were selected as dependent variables. A model was established by the random forest algorithm and a new zeolite was predicted based on it. The results of model prediction were in good agreement with the experimental results. The R² of the n-C₁₀ conversion, C₃/C₇ ratio, and i-C₄/n-C₄ ratio were 0.9866, 0.9845, and 0.9922, and the minimum root mean square error values were 0.0163, 0.101, and 0.0211, respectively. These results can provide reference for the development of high performance hydrocracking catalyst and technology.

Key words: Hydrocracking, Machine learning, Y zeolite, n-Decane, Acid, Pore structure

Qianli Ma, Hong Nie, Ping Yang, Jianqiang Liu, Hongyi Gao, Wei Wang, Songtao Dong. Insights into Structure-Activity Relationships between Y Zeolites and their n-C₁₀ Hydrocracking Performances via Machine Learning Approaches[J]. Chinese Journal of Catalysis, 2025, 71: 187-196.

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URL: https://www.cjcatal.com/EN/10.1016/S1872-2067(24)60259-7

https://www.cjcatal.com/EN/Y2025/V71/I4/187

Figures/Tables 7

Fig. 1. Studying the basic process of catalyst structure-activity relationship through machine learning.

Fig. 2. Catalyst evaluation results. (a) Conversion versus temperature curve. (b) C3/C7 versus temperature curve. (c) i-C4/n-C4 versus temperature curve. (d) isomerization selectivity versus conversion curve.

Fig. 3. Pearson correlation coefficient analysis of zeolite structure variables. (a) The correlation coefficients among all variables. (b) The correlation coefficient between the selected independent variables.

Fig. 4. Machine learning prediction results of n-decane hydrocracking reaction. (a1-a3) Training set; (b1-b3) Prediction set.

Table 1 Thermodynamic calculation of n-butane isomerization reaction. K = i-C4/n-C4.

T/°C	△H/J·mol^-1	△G/J·mol^-1	K
310	-8203.6	686.5	0.87
330	-8177.0	991.0	0.82
350	-8149.3	1294.5	0.78
370	-8120.8	1597.2	0.74

Fig. 5. Univariate prediction of n-decane hydrocracking reaction using random forest model. Standard conditions: cell parameters 2.4600 nm, acid content 1400 μmol·g-1, acid strength 350 °C, B/L 8.0; mesopore volume 0.08 cm3·g-1; micropore volume: 0.300 cm3·g-1. (a1-a6) Conversion; (b1-b6): C3/C7; (c1-c6): i-C4/n-C4.

Fig. 6. Machine learning prediction results of n-decane hydrocracking reaction for Y24 catalyst. (a) Conversion; (b) C3/C7; (c) i-C4/n-C4.

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Insights into Structure-Activity Relationships between Y Zeolites and their n-C₁₀ Hydrocracking Performances via Machine Learning Approaches

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