丁二烯半加氢反应中Pd-Ag纳米催化剂结构-选择性耦合关系解析

doi:10.1016/S1872-2067(26)65078-4

催化学报 ›› 2026, Vol. 87: 342-352.DOI: 10.1016/S1872-2067(26)65078-4

丁二烯半加氢反应中Pd-Ag纳米催化剂结构-选择性耦合关系解析

秦家祥^a^,¹, 张松培^b^,¹, 李星局^c^,¹, 陈鑫泰^a, 赵佳^b^,^*(), 牟效玲^a, 宋宪根^c^,^*(), 严丽^c, 林荣和^a^,^*(), 丁云杰^a^,^c^,^*()

^a 浙江师范大学杭州高等研究院, 先进催化教育部重点实验室, 全省先进催化与吸附材料重点实验室, 浙江杭州 311231
^b 浙江工业大学工业催化研究所, 全省催化剂表界面科学与工程重点实验室, 绿色化学合成与转化技术全国重点实验室, 浙江杭州 310014
^c 大连化学物理研究所, 催化基础全国重点实验室, 辽宁大连 116023

收稿日期:2025-11-24 接受日期:2026-01-08 出版日期:2026-08-18 发布日期:2026-06-24
通讯作者: ^*电子信箱: jiazhao@zjut.edu.cn (赵佳),
xiangensong@dicp.ac.cn (宋宪根),
catalysis.lin@zjnu.edu.cn (林荣和),
作者简介:¹共同第一作者.
基金资助:
国家自然科学基金(22372150);国家自然科学基金(22408364);国家自然科学基金(22402179);国家自然科学基金(22472149);国家重点研发计划(2021YFA1501802);浙江省自然科学基金(LQ24B030012);浙江省重点研发计划(2023C01211);金华市科技局(2022-1-078);浙江师范大学“先进催化材料”教育部重点实验室和“全省先进催化与吸附材料重点实验室”培育项目(2025ZY01096)

Decoding structure-selectivity interplay in Pd-Ag nanocatalysts for butadiene semi-hydrogenation

Jiaxiang Qin^a^,¹, Songpei Zhang^b^,¹, Xingju Li^c^,¹, Xintai Chen^a, Jia Zhao^b^,^*(), Xiaoling Mou^a, Xiangen Song^c^,^*(), Li Yan^c, Ronghe Lin^a^,^*(), Yunjie Ding^a^,^c^,^*()

^a Key Laboratory of the Ministry of Education for Advanced Catalysis Materials, Zhejiang Key Laboratory of Advanced Catalysis and Adsorption Materials, Hangzhou Institute of Advanced Studies, Zhejiang Normal University, Hangzhou 311231, China
^b Zhejiang Key Laboratory of Surface and Interface Science and Engineering for Catalysts, State Key Laboratory of Green Chemical Synthesis and Conversion, Institute of Industrial Catalysis of Zhejiang University of Technology, Hangzhou 310014, Zhejiang, China
^c The State Key Laboratory of Catalysis, Dalian Institute of Chemical Physics, Chinese Academy of Sciences, Dalian 116023, Liaoning, China

Received:2025-11-24 Accepted:2026-01-08 Online:2026-08-18 Published:2026-06-24
Contact: catalysis.lin@zjnu.edu.cn (R. Lin),
About author:¹Contributed equally to this work.
Supported by:
National Natural Science Foundation of China(22372150);National Natural Science Foundation of China(22408364);National Natural Science Foundation of China(22402179);National Natural Science Foundation of China(22472149);National Key Research and Development Program of China(2021YFA1501802);Zhejiang Provincial Natural Science Foundation of China(LQ24B030012);Zhejiang Provincial Key R&D Project(2023C01211);Jinhua Science and Technology Plan Project(2022-1-078);Research Fund of Key Laboratory of the Ministry of Education for Advanced Catalysis Materials, Zhejiang Key Laboratory of Advanced Catalysis and Adsorption Materials, Zhejiang Normal University(2025ZY01096)

摘要/Abstract

摘要：

在多相催化反应中, 实现复杂反应网络中产物选择性的精准调控始终是催化科学面临的核心挑战, 其根本原因在于催化剂几何结构、电子结构及活性位分布等多种因素之间存在高度耦合关系, 难以独立解析各因素对反应路径与产物分布的影响.

以1,3-丁二烯选择性半加氢反应为模型体系, 本文围绕Pd-Ag双金属纳米催化剂, 系统研究了金属粒径与合金组成对反应活性及产物选择性的协同调控作用, 旨在揭示双金属体系中结构与选择性之间的内在关联. 通过调控还原温度与Ag/Pd比例, 构建了一系列粒径与电子结构可控的单金属Pd及双金属Pd-Ag纳米催化剂, 实现了对几何效应与电子效应的有效解耦. 结合动力学分析、化学吸附表征以及密度泛函理论(DFT)计算, 系统建立了催化剂结构参数与产物分布之间的定量关联. 结果表明, Pd-Ag合金中活性位聚集体尺寸和Pd平均价态是决定产物选择性的关键描述符. 当Pd-Ag合金颗粒尺寸增大、Pd呈现相对低价态时, 1-丁烯在催化剂表面的吸附显著减弱, 其脱附过程在动力学上更具优势, 从而有效抑制了进一步加氢生成丁烷及异构化生成2-丁烯的反应路径, 实现了对1-丁烯的选择性生成. 实验结果表明, 优化后的Pd-Ag催化剂在接近完全转化条件下可获得高达66%的1-丁烯选择性, 同时保持超过98%的丁烯总选择性, 并在长时间反应过程中表现出优异的稳定性. 动力学与化学吸附结果表明, 大尺寸Pd-Ag合金对丁二烯具有更强的吸附能力, 而对生成的1-丁烯则表现出更高的脱附倾向. DFT计算进一步揭示, 在大尺寸Pd-Ag合金表面, 1-丁烯生成路径的能垒显著低于生成热力学更稳定的2-丁烯及丁烷路径, 从本质上阐明了电子调控与几何结构协同作用对反应选择性的决定性影响.

综上, 本文通过系统解耦Pd-Ag双金属纳米催化剂中几何结构与电子结构对选择性加氢反应的协同调控机制, 建立了清晰的结构-选择性关联框架, 为双金属催化剂的理性设计提供了可推广的思路, 也为复杂反应网络中高附加值目标产物的精准合成提供了重要的理论依据和实验指导.

关键词: 选择性加氢, 选择性描述符, 双金属催化剂, 反应动力学, 密度泛函理论

Abstract:

Precise control over product selectivity in heterogeneous catalysis remains a key challenge due to the complex interplay of structural and electronic factors. Here, we demonstrate delicate tuning of product distribution in 1,3-butadiene semi-hydrogenation by engineering the size and composition of Pd-Ag nanostructures. By systematically decoupling size and electronic effects, we identify critical selectivity descriptors and establish structure-selectivity correlations across both monometallic and bimetallic series. The thresholds of ensemble size and Pd valence state for the formation of distinct products are experimentally determined. Integrating kinetic analysis, chemisorption studies, and density functional theory calculations, we show that increased ensemble size and Ag incorporation weaken 1-butene binding and elevate hydrogenation barriers, enabling selective formation of 1-butene (up to 66%) over thermodynamically favored 2-butenes. These insights reveal the fundamental roles of geometric and electronic modulation in governing selectivity and offer a generalizable framework for the rational design of multifunctional bimetallic catalysts.

Key words: Selective hydrogenation, Selectivity descriptor, Bimetallic catalysts, Kinetics, Density functional theory

秦家祥, 张松培, 李星局, 陈鑫泰, 赵佳, 牟效玲, 宋宪根, 严丽, 林荣和, 丁云杰. 丁二烯半加氢反应中Pd-Ag纳米催化剂结构-选择性耦合关系解析[J]. 催化学报, 2026, 87: 342-352.

Jiaxiang Qin, Songpei Zhang, Xingju Li, Xintai Chen, Jia Zhao, Xiaoling Mou, Xiangen Song, Li Yan, Ronghe Lin, Yunjie Ding. Decoding structure-selectivity interplay in Pd-Ag nanocatalysts for butadiene semi-hydrogenation[J]. Chinese Journal of Catalysis, 2026, 87: 342-352.

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图/表 6

Fig. 1. Design of Pd and Pd-Ag nanocatalysts, conceptual approaches, and research targets. Abbreviations of different molecules were denoted in the parenthesis.

Fig. 2. Characterizations of the developed key catalysts. (a) PXRD of the key catalysts. (b) The zoomed patterns at 2θ = 37°-41° showed the shift of the diffraction lines. (c-l) TEM images of the key catalysts, accompanied with the particle size distributions (insets). (j,k) Elemental color mapping images of different PdAg catalysts. The core-level Pd 3d (l,m) and Ag 3d (n) XPS spectra of the key catalysts. The deconvolution results were shown as the shadowed peaks. Dashed lines indicate the shifts of the binding energies that strongly hints the electronic transfer from Ag to Pd at the increasing particle sizes. (o) Bader charge analysis of small and large PdAg alloys. Large PdAg ensembles shows a higher average charge transfer from Ag to Pd than the small analogues (0.104 vs. 0.097 e).

Fig. 3. Catalytic performance of the developed catalysts in butadiene hydrogenation. (a) The conversion and butene selectivity as a function of bed temperature on monometallic and bimetallic catalysts. (b) The product distributions at near complete conversion at different H2:BD ratios. (c) Major products on small (s) and large (l) Pd and Pd-Ag ensembles. (d) Long-term stability performance of PdAg76.7. Reaction conditions: Wcat = 30 mg, Ftotal = 75 mL min-1, GHSV = 150000 mL gcat-1 h-1, P = 1 bar, a, H2:BD = 10; (d) H2:BD = 50 and T = 338 K. (e,f) Comparison on the catalytic performances of different catalysts in BD hydrogenation at approaching full conversion; yields of total butenes and 1-butene selectivity (e), heatmap of bed temperatures (f), catalyst codes (g).

Fig. 4. Reaction kinetics on different PdAd nanoalloys. The product distribution as a function of contact time in butadiene (a,b) and 1-butene (d) hydrogenation. (c) The conversion of 1-butene as a function of bed temperature. Reaction conditions: P = 1 bar, (a,b,d) GHSV was between 40000-1440000 cm3 gcat-1 h-1 by varying both the catalyst weight and total gas flow rate, H2:BD(1B) = 20, T = 313 K for (a,b) and 303 K for (d). (c) Wcat = 10 mg, H2:1B = 10, Ftotal = 75 mL min-1, GHSV = 450000 mL gcat-1 h-1. (e) The global activation energies, and partial reaction orders of H2 (f) and butadiene (g). Chemisorption properties: BD-TPD (h) and 1-butene TPD (i) profiles. (j) The relative desorption amount between BD and 1B (ABD:A1B) and the differences between their peak desorption temperatures (TBD − T1B). (k) Schematic illustrations on the different reaction paths on small and large Pd-Ag alloys.

Fig. 5. Structure-performance correlations. (a) The formation zones of different butadiene hydrogenation products on Pd and PdAg ensembles of varying particle sizes and Pd valent states. Correlations between Sbutenes (S1B) and average particle size of Pd or PdAg ensembles (b) and average valent state of Pd (c). (d) Critical selectivity descriptors in Pd and PdAg systems. Zone 1 for butane, zone 2 for 1-butene, and zone 3 for 2-butenes.

Fig. 6. DFT simulations of BD hydrogenation reaction coordinate on different model catalysts. (a,d) The energy profiles of each elementary steps. (b,e) Comparison on the energy barriers of three transient states. (c,f) The simplified reaction cycles on small PdAg ensembles (PdAg-s). (a-c) BD→trans-2B→butane path; (d-f) the BD→1B→butane path.

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丁二烯半加氢反应中Pd-Ag纳米催化剂结构-选择性耦合关系解析

Decoding structure-selectivity interplay in Pd-Ag nanocatalysts for butadiene semi-hydrogenation

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