催化作用
丙烷
脱氢
合理设计
材料科学
概化理论
丙烯
产量(工程)
环氧丙烷
氧化物
计算机科学
过度拟合
接口(物质)
生物系统
响应面法
集合(抽象数据类型)
组合化学
分子描述符
绝热过程
多相催化
金属
表征(材料科学)
工作(物理)
化学工程
实验数据
工艺工程
非线性系统
钥匙(锁)
作者
Qiwen Guo,Jun Hu,Qingchun Yang,Jingsong Guan,Dawei Zhang
标识
DOI:10.1021/acsami.5c21218
摘要
The rational design of high-performance catalysts for CO2-assisted propane dehydrogenation (CO2–PDH) is hindered by the complex interplay among catalyst properties, preparation parameters, and reaction conditions. Herein, this study develops an interpretable machine learning (ML) framework that accelerates the discovery of optimal catalysts and deciphers the underlying structure-performance relationships. A meticulously curated data set of 606 experimental data points was used to train and optimize seven ML models. The optimized XGBoost model demonstrated superior predictive accuracy (test R2 = 0.966) for propane conversion, propylene selectivity, and yield. Shapley Additive exPlanations (SHAP) analysis quantitatively ranked the importance of 17 input features, revealing that catalyst descriptors (45.4%) and reaction conditions (37.2%) dominated the catalytic performance. Specific surface area, the primary support material, and time-on-stream were identified as the most critical descriptors governing the catalytic interface and activity. Partial dependence plots further elucidated the nonlinear influence of these key parameters on the target outputs. The framework was subsequently employed for multiobjective optimization, leading to the identification of Pareto-optimal catalysts (e.g., Cr2O3–Co/MSS-2-La2O3) achieving a remarkable propylene yield of 74.95%. Independent experimental validation on unseen catalysts confirmed the model’s exceptional generalizability and accuracy, with prediction errors ≤ 4.34%. This work provides a robust, data-driven strategy for the rational design of high-performance catalytic materials by translating black-box predictions into actionable design principles.
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