催化学报

催化学报

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CeAlO3镶嵌镍纳米颗粒抗积碳甲烷干重整催化剂

马忠臣a, 尹美怡a, 徐润b, 张荣俊b, 兰天a, 顾文丽a, 陈国庆a, 路勇a,c,*   

  1. a华东师范大学化学与分子工程学院, 石油化工分子转化与反应工程全国重点实验室, 上海市绿色化学与化工过程绿色化重点实验室, 上海 200062;
    b中石化石油化工科学研究院有限公司, 北京 100083;
    c崇明生态研究院, 上海 202151
  • 收稿日期:2025-11-19 接受日期:2025-12-22
  • 通讯作者: *电子信箱: ylu@chem.ecnu.edu.cn (路勇).
  • 基金资助:
    国家自然科学基金(22572054, 22272053, 22072043); 国家重点研发计划(2023YFA1507903, 2023YFB3810602).

Coking-resistant CeAlO3-Socketed Nickel Nanocatalysts for dry reforming of methane

Zhongchen Maa, Meiyi Yina, Run Xub, Rongjun Zhangb, Tian Lana, Wenli Gua, Guoqing Chena, Yong Lua,c,*   

  1. aState Key Laboratory of Petroleum Molecular & Process Engineering, Shanghai Key Laboratory of Green Chemistry and Chemical Processes, School of Chemistry and Molecular Engineering, East China Normal University, Shanghai 200062, China;
    bSINOPEC Research Institute of Petroleum Processing Co., Ltd., Beijing 100083, China;
    cInstitute of Eco-Chongming (IEC), Shanghai 202151, China
  • Received:2025-11-19 Accepted:2025-12-22
  • Contact: *E-mail: ylu@chem.ecnu.edu.cn (Y. Lu).
  • Supported by:
    National Natural Science Foundation of China (22572054, 22272053, 22072043), the National Key Research and Development Program of China (2023YFA1507903, 2023YFB3810602), and the support partially provided by the SINOPEC Research Institute of Petroleum Processing Co., Ltd.

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摘要: 推进碳基能源化工体系的绿色可持续发展, 是当前国家“双碳”战略实施的必然要求. 从绿色碳科学分子视角看, CH4和CO2能源化工利用的开发和应用, 是一项赋能“碳减排”、服务“碳中和”的重要路径. 将CO2与CH4通过重整反应(DRM, 甲烷干重整)制成合成气并经下游催化技术转化可同时实现天然气(主要成分为CH4)和CO2的化工利用, 是规模化消纳CO2、助力“碳减排”值得重点攻关的可行技术之一. 作为最具工业应用潜力的镍基催化剂, 其抗积碳、抗烧结性能依然面临严峻挑战, 这极大制约了DRM过程的商业化开发.
基于此, 本研究提出了一种限域结构耦合界面氧化-还原工程的催化剂构筑策略, 旨在为Ni基催化剂的易积碳和易烧结问题提供解决方案. 具体而言, 通过H2还原诱导Ni颗粒从Ce1Al0.95Ni0.05Ox复合氧化物中析出, 并同步结晶生成CeAlO3, 可控构建出CeAlO3镶嵌Ni纳米颗粒的限域耦合特定界面的独特结构. 尤其是, 通过改变还原温度(700‒900 °C)实现了系列Ni颗粒析出程度可控且Ni-CeAlO3界面量可调的Ce1Al0.95Ni0.05Ox-T催化剂的制备. 对所制得催化剂进行了扫描电镜、透射电镜、分散度、催化活性、失活率及转换频率等分析表征, 结合理论计算, 深入研究了还原温度对界面结构以及催化活性和稳定性的影响. 结果表明, 经750 °C还原制得的催化剂, Ni纳米颗粒(3-4 nm)均匀嵌入到CeAlO3载体中, 形成了丰富的Ni-CeAlO3界面结构. 所得Ce1Al0.95Ni0.05Ox-750催化剂在常压、700 °C, 15 L gcat-1 h-1, CH4/CO2 = 1/1(无稀释)的反应条件下, 连续运行500 h无失活且无积碳生成. 研究表明, Ni-CeAlO3界面活性位相对于Ni颗粒表面位点, 对甲烷的活化能力有所削弱但同时对CO2的活化能力得到了明显增强. 在此基础上, 借助原位红外漫反射光谱和13C同位素标记实验研究, 揭示了Ni-CeAlO3界面氧化-还原催化循环机理: 在反应气氛中CO2优先在Ni-CeAlO3界面位点上活化, 生成CO与活性氧物种(O*); 随后, 界面的O*以CH3O*中间体的形式参与CH4的活化并进一步转化生成CO和H2, 完成界面氧化-还原催化循环. 这种串行反应机制实现了CO2和CH4分子的计量转化, 从本质上抑制了传统甲烷裂解机理上由于O*供给以及传递速率不足引起的积碳, 赋予催化剂突出的抗积碳性能.
综上, 本文针对Ni基DRM催化剂易积碳和易烧结的问题, 发展了限域结构耦合界面氧化-还原工程的催化剂构筑策略, 研制出兼具抗积碳和抗烧结性能的Ni基催化剂, 阐明了基于CO2优先活化提供活性氧物种(O*)接力活化转化CH4的串行反应新机理. 本研究为设计具有工业应用前景的高效镍基DRM催化剂提供了新思路和可行技术方案.

关键词: 甲烷干重整, 抗积碳, 镍基催化剂, 界面催化, CeAlO3

Abstract: Nickel-based catalysts are regarded as the most promising candidates for industrial dry reforming of methane (DRM), yet severe coking and metal sintering impede their commercial viability. Herein, we report a CeAlO3-socketed Ni nanocatalyst with extensive Ni-CeAlO3 interfaces, demonstrating coke-free stability with no deactivation over 500 h test at 700 °C for a feed of CH4/CO2 = 1/1 (undiluted). The socket-structured catalyst was obtained via H2-reduction-triggered Ni exsolution and simultaneous formation of CeAlO3 from a Ce1Al0.95Ni0.05Ox composite oxide. A socketed structure featuring extensive Ni-CeAlO3 interface was achieved upon reduction at 750 °C, which essentially modulated the catalytic activation kinetics of both CO2 and CH4. In-situ diffused reflectance infrared Fourier transformed spectroscopy and isotope-labeling experiments were performed to gain insight into the interfacial catalysis, revealing that CO2 was preferentially activated at the Ni-CeAlO3 interface to form CO and O*, and CH4 was subsequently oxidized by O* to form H2 and another CO through formation of CH3O* intermediates. Such tandem reaction pathway led to stoichiometric conversion of CO2 and CH4 molecules thereby imparting our catalyst to high coking resistance. Our findings shed light on the rational design of a valid Ni-based DRM catalyst with substantial potential for industrial application.

Key words: Dry reforming of methane, Coking resistance, Nickel catalyst, Interface catalysis, CeAlO3