负载型Pd/SnO2催化剂低温催化甲烷燃烧

催化学报 ›› 2017, Vol. 38 ›› Issue (8): 1322-1329.

负载型Pd/SnO₂催化剂低温催化甲烷燃烧

赵振阳, 王博伟, 马健, 詹望成, 王丽, 郭杨龙, 郭耘, 卢冠忠

华东理工大学化学与分子工程学院工业催化研究所先进材料重点实验室, 上海 200237

收稿日期:2017-03-26 修回日期:2017-05-18 出版日期:2017-08-18 发布日期:2017-08-04
通讯作者: 王丽, 郭耘
基金资助:
国家高技术研究发展计划（2015AA034603）；国家重点研发计划（2016YFC0204300）；国家自然科学基金（21171055，21333003，21571061）；上海市曙光计划（12SG29）；上海市科委（15DZ1205305）.

Catalytic combustion of methane over Pd/SnO₂ catalysts

Zhenyang Zhao, Bowei Wang, Jian Ma, Wangcheng Zhan, Li Wang, Yanglong Guo, Yun Guo, Guanzhong Lu

Key Laboratory for Advanced Materials and Research Institute of Industrial Catalysis, School of Chemistry and Molecular Engineering, East China University of Science and Technology, Shanghai 200237, China

Received:2017-03-26 Revised:2017-05-18 Online:2017-08-18 Published:2017-08-04
Supported by:
This work was supported by the National High Technology Research and Development Program of China (2015AA034603), the National Key Research and Development Program of China (2016YFC0204300), the National Natural Science Foundation of China (21171055, 21333003, 21571061), the "Shu Guang" Project of the Shanghai Municipal Education Commission (12SG29), and the Commission of Science and Technology of Shanghai Municipality (15DZ1205305).

摘要/Abstract

摘要：

天然气储量巨大，被广泛应用于发电和工业窑炉等.甲烷作为天然气中最主要的成分，是氢碳比最高的碳氢化合物，其温室效应显著.因此，不完全燃烧所引起的CH₄排放，不仅导致能源浪费，同时也可造成环境污染.与传统火焰燃烧相比，CH₄催化燃烧具有更高的燃烧效率，并可显著地减少大气污染物（CO，NO_x和未完全燃烧的烃类）的排放.
贵金属Pd催化剂对CH₄催化燃烧表现出优异的催化性能，其中Pd颗粒的尺寸、Pd的化学状态、载体性质及其与Pd之间的相互作用等对其活性有显著影响.本文以不同温度（600，800，1000和1200℃）焙烧所得SnO₂为载体，通过等体积浸渍法制备了Pd/SnO₂催化剂，研究了SnO₂焙烧温度对CH₄催化燃烧性能的影响.结果表明，所制备的SnO₂均为锐钛矿结构，并且随着SnO₂焙烧温度的升高，晶型愈加完美，晶粒尺寸显著增大.催化剂中引入的Pd以高分散形式存在，CH₄催化燃烧反应活性随着载体SnO₂焙烧温度的升高而显著提高，其中Pd/SnO₂（1200）表现出最高的CH₄燃烧活性，起燃温度和最低全转化温度分别为265和390℃.在反应温度为300℃时，Pd/SnO₂（1200）上甲烷的反应速率是Pd/SnO₂（600）的36倍.XPS等结果表明，随着SnO₂焙烧温度的升高，Pd的化学状态也有所差异：对于低温焙烧的SnO₂（< 800℃），Pd以Pd⁴⁺的形式进入到SnO₂晶格内；随着焙烧温度的升高（>1000℃），Pd以Pd²⁺物种的形式存在于载体表面.结合活性评价结果推测，Pd的化学状态可能并非是影响催化剂活性的最关键因素.TEM等结果表明，Pd/SnO₂（1000）上PdO的（101）晶面与载体SnO₂的（101）晶面相近，分别为0.2641 nm和0.2638 nm.O₂-TPD和CH₄-TPR结果表明，Pd/SnO₂（1200）催化剂上单位Pd原子上O₂的脱附量是Pd/SnO₂（600）的3倍，单位Pd原子上CH₄的消耗量比催化剂Pd/SnO₂（600）高出45%.因此，PdO和SnO₂在构型上存在的晶面匹配可提高催化剂对O₂的活化能力.
综上所述，SnO₂和贵金属之间的晶格匹配有利于氧在Pd-SnO₂界面的活化，同时载体SnO₂中的晶格氧亦可以通过“氧反溢流机理”补充到表面PdO/Pd上，从而增强催化剂对O₂的吸附和活化能力，并提高CH₄催化燃烧反应性能.升高SnO₂的焙烧温度可强化SnO₂和贵金属之间的晶格匹配，从而使催化剂活性随着SnO₂焙烧温度升高而增大.

关键词: 甲烷燃烧, 钯, 二氧化锡, 晶面匹配, 氧活化

Abstract:

SnO₂-supported Pd catalysts were prepared and the effects of the support calcination tempera-ture on the subsequent catalytic activity during methane combustion were investigated. The physicochemical properties of the Pd/SnO₂ were characterized by X-ray diffraction, high-resolution transmission electron microscopy, X-ray photoelectron spectroscopy, oxygen temperature-programmed desorption and CH₄ temperature-programmed surface reaction. Only crystalline Pd species were found on the catalysts fabricated from the supports calcined above 800℃. It was also determined that lattice geometry matching between PdO and SnO₂ in the catalyst made with a support calcined at 1200℃ facilitated oxygen activation from SnO₂ to vacant oxygen sites on the PdO/Pd surface via the back-spillover of oxygen. This effect in turn enhanced the catalytic combustion process. The activity of this material was clearly increased compared with the catalysts that did not exhibit lattice matching between the PdO and support.

Key words: Methane combustion, Palladium, Tin oxide, Lattice match, Oxygen activation

赵振阳, 王博伟, 马健, 詹望成, 王丽, 郭杨龙, 郭耘, 卢冠忠. 负载型Pd/SnO₂催化剂低温催化甲烷燃烧[J]. 催化学报, 2017, 38(8): 1322-1329.

Zhenyang Zhao, Bowei Wang, Jian Ma, Wangcheng Zhan, Li Wang, Yanglong Guo, Yun Guo, Guanzhong Lu. Catalytic combustion of methane over Pd/SnO₂ catalysts[J]. Chinese Journal of Catalysis, 2017, 38(8): 1322-1329.

×
扫码分享

导出引用管理器 EndNote|Ris|BibTeX

链接本文: https://www.cjcatal.com/CN/

https://www.cjcatal.com/CN/Y2017/V38/I8/1322

参考文献

[1] P. Gélin, M. Primet, Appl. Catal. B, 2002, 39, 1-37.
[2] L. S. Escandon, S. Ordonez, A. Vega, F. V. Díez, J. Hazard. Mater., 2008, 153, 742-750.
[3] J. H. Li, X. Liang, S. C. Xu, J. M. Hao, Appl. Catal. B, 2009, 90, 307-312.
[4] G. H. Zhu, J. Y. Han, D. Y. Zemlyanov, F. H. Ribeiro, J. Am. Chem. Soc., 2004, 126, 9896-9897.
[5] Q. Sun, X. L. Xu, H. G. Peng, X. Z. Fang, W. M. Liu, J. W. Ying, F. Yu, X. Wang, Chin. J. Catal., 2016, 37, 1293-1302.
[6] L. F. Liotta, G. Di Carlo, G. Pantaleo, G. Deganello, Catal. Com-mun., 2005, 6, 329-336.
[7] L. F. Yang, C. K. Shi, X. E. He, J. X. Cai, Appl. Catal. B, 2002, 38, 117-125.
[8] D. Ciuparu, E. Perkins, L. Pfefferle, Appl. Catal. A, 2004, 263, 145-153.
[9] K. Eguchi, H. Arai, Appl. Catal. A, 2001, 222, 359-367.
[10] Y. H. Chin, C. Buda, M. Neurock, E. Iglesia, J. Am. Chem. Soc., 2013, 135, 15425-15442.
[11] J. Nilsson, P. A. Carlsson, S. Fouladvand, N. M. Martin, J. Gustafson, M. A. Newton, E. Lundgren, H. Grönbeck, M. Skoglundh, ACS Catal., 2015, 5, 2481-2489.
[12] P. Gélin, M. Primet, Appl. Catal. B, 2002, 39, 1-37.
[13] R. F. Hicks, H. Qi, M. L. Young, R. G. Lee, J. Catal., 1990, 122, 280-294.
[14] R. F. Hicks, H. Qi, M. L. Young, R. G. Lee, J. Catal., 1990, 122, 295-306.
[15] J. H. Park, J. H. Cho, Y. J. Kim, E. S. Kim, H. S. Han, C. H. Shin, Appl. Catal. B, 2014, 160-161, 135-143.
[16] H. Yoshida, T. Nakajima, Y. Yazawa, T. Hattori, Appl. Catal. B, 2007, 71, 70-79.
[17] S. H. Oh, P. J. Mitchell, R. M. Siewert, J. Catal., 1991, 132, 287-301.
[18] S. H. Oh, P. J. Mitchell, Appl. Catal. B, 1994, 5, 165-179.
[19] T. P. Senftle, A. C. T. van Duin, M. J. Janik, ACS Catal., 2015, 5, 6187-6199.
[20] J. Xu, L. K. Ouyang, W. Mao, X. J. Yang, X. C. Xu, J. J. Su, T. Z. Zhuang, H. Li, Y. F. Han, ACS Catal., 2012, 2, 261-269.
[21] F. X. Yin, S. F. Ji, P. Y. Wu, F. C. Zhao, C. Y. Li, J. Catal., 2008, 257, 108-116.
[22] Y. Lou, J. Ma, W. D. Hu, Q. G. Dai, L. Wang, W. C. Zhan, Y. L. Guo, X. M. Cao, Y. Guo, P. Hu, G. Z. Lu, ACS Catal., 2016, 6, 8127-8139.
[23] M. Cargnello, J. J. D. Jaen, J. C. H. Garrido, K. Bakhmutsky, T. Montini, J. J. C. Gamez, R. J. Gorte, P. Fornasiero, Science, 2012, 337, 713-717.
[24] F. L. Lei, Z. S. Li, L. T. Ye, Y. L. Wang, S. Lin, Int. J. Hydrogen Energy, 2016, 41, 255-264.
[25] C. Liu, H. Xian, Z. Jiang, L. H. Wang, J. Zhang, L. R. Zheng, Y. S. Tan, X. Q. Li, Appl. Catal. B, 2015, 176-177, 542-552.
[26] X. J. Yao, Y. Xiong, W. X. Zou, L. Zhang, S. Q. Wu, X. Dong, F. Gao, Y. Deng, C. J. Tang, Z. Chen, L. Dong, Y. Chen, Appl. Catal. B, 2014, 144, 152-165.
[27] K. Sekizawa, H. Widjaja, S. Maeda, Y. Ozawa, K. Eguchi, Appl. Catal. A, 2000, 200, 211-217.
[28] K. Sekizawa, H. Widjaja, S. Maeda, Y. Ozawa, K. Eguchi, Catal. Today, 2000, 59, 69-74.
[29] H. Widjaja, K. Sekizawa, K. Eguchi, H. Arai, Catal. Today, 1997, 35, 197-202.
[30] H. Widjaja, K. Sekizawa, K. Eguchi, H. Arai, Catal. Today, 1999, 47, 95-101.
[31] V. Bratan, C. Munteanu, C. Hornoiu, A. Vasile, F. Papa, R. State, S. Preda, D. Culita, N. I. Ionescu, Appl. Catal. B, 2017, 207, 166-173.
[32] X. L. Zou, Z. B. Rui, S. Q. Song, H. B. Ji, J. Catal., 2016, 338, 192-201.
[33] W. Z. Li, L. Kovarik, D. H. Mei, M. H. Engelhard, F. Gao, J. Liu, Y. Wang, C. H. F. Peden, Chem. Mater., 2014, 26, 5475-5481.
[34] G. N. Vayssilov, Y. Lykhach, A. Migani, T. Staudt, G. P. Petrova, N. Tsud, T. Skála, A. Bruix, F. Illas, K. C. Prince, V. Matolin, K. M. Neyman, J. Libuda, Nat. Mater., 2011, 10, 310-315.
[35] G. Agostini, C. Lamberti, R. Pellegrini, G. Leofanti, F. Giannici, A. Longo, E. Groppo, ACS Catal., 2014, 4, 187-194.
[36] U. Oemar, K. Hidajat, S. Kawi, Appl. Catal. A, 2011, 402, 176-187.
[37] K. Eguchi, H. Arai, Appl. Catal. A, 2001, 222, 359-367.
[38] H. Lorenz, Q. Zhao, S. Turner, O. I. Lebedev, G. Van Tendeloo, B. Klötzer, C. Rameshan, K. Pfaller, J. Konzett, S. Penner, Appl. Catal. A, 2010, 381, 242-252.
[39] Y. Chu, D. Mallin, M. Amani, M. J. Platek, O. J. Gregory, Sens. Actuators B, 2014, 197, 376-384.
[40] D. N. Gao, C. X. Zhang, S. Wang, Z. S. Yuan, S. D. Wang, Catal. Com-mun., 2008, 9, 2583-2587.
[41] M. Schmal, M. M. V. M. Souza, V. V. Alegre, M. A. P. da Silva, D. V. César, C. A. C. Perez, Catal. Today, 2006, 118, 392-401.
[42] R. V. Gulyaev, A. I. Stadnichenko, E. M. Slavinskaya, A. S. Ivanova, S. V. Koscheev, A. I. Boronin, Appl. Catal. A, 2012, 439-440, 41-50.
[43] K. R. Priolkar, P. Bera, P. R. Sarode, M. S. Hegde, S. Emura, R. Kumashiro, N. P. Lalla, Chem. Mater., 2002, 14, 2120-2128.
[44] J. Jansson, A. E. C. Palmqvist, E. Fridell, M. Skoglundh, L. Österlund, P. Thormählen, V. Langer, J. Catal., 2002, 211, 387-397.
[45] Y. Lou, L. Wang, Y. H. Zhang, Z. Y. Zhao, Z. G. Zhang, G. Z. Lu, Y. Guo. Catal. Today, 2011, 175, 610-614
[46] L. M. T. Simplício, S. T. Brandão, E. A. Sales, L. Lietti, F. Bozon Verduraz, Appl. Catal. B, 2006, 63, 9-14
[47] Y. Ozawa, Y. Tochihara, A. Watanabe, M. Nagai, S. Omi, Appl. Catal. A, 2004, 258, 261-267.
[48] Y. Liu, C. Wen, Y. Guo, G. Z. Lu, Y. Q. Wang, J. Phys. Chem. C, 2010, 114, 9889-9897.
[49] L. S. Escandón, D. Niño, E. Díaz, S. Ordóñez, F. V. Díez, Catal. Com-mun., 2008, 9, 2291-2296.
[50] J. N. Carstens, S. C. Su, A. T. Bell, J. Catal., 1998, 176, 136-142.
[51] L. F. Yang, C. K. Shi, X. E. He, J. X. Cai, Appl. Catal. B, 2002, 38, 117-125.
[52] C. K. Shi, L. F. Yang, J. X. Cai, Fuel, 2007, 86, 106-112.
[53] D. Martin, D. Duprez, J. Phys. Chem., 1996, 100, 9429-9438.
[54] S. Y. Christou, A. M. Efstathiou, Top. Catal., 2007, 42-43, 351-355.
[55] C. N. Costa, S. Y. Christou, G. Georgiou, A. M. Efstathiou, J. Catal., 2003, 219, 259-272.
[56] S. Y. Christou, C. N. Costa, A. M. Efstathiou, Top. Catal., 2004, 30-31, 325-331.

负载型Pd/SnO₂催化剂低温催化甲烷燃烧

Catalytic combustion of methane over Pd/SnO₂ catalysts

PDF

可视化

摘要/Abstract

引用本文

使用本文

扫码分享

参考文献

相关文章 15

编辑推荐

Metrics

[1]	夏思源, 李奇远, 张仕楠, 许冬, 林秀, 孙露菡, 许景三, 陈接胜, 李国栋, 李新昊. Pd纳米立方体异质结尺寸依赖的电子界面效应对苯酚加氢反应的促进作用[J]. 催化学报, 2023, 49(6): 180-187.
[2]	李倩, 刘䶮, 李灿. 钯催化不对称烯丙基化/去对称化反应合成无保护基的2-喹啉酮骨架环状氨基酸[J]. 催化学报, 2023, 47(4): 222-228.
[3]	王海凤, 王凡, 李小鹏, 肖琪, 罗维, 许景三. 光照条件下AuPd合金纳米颗粒上原位形成缺电子Pd位点促进高效的光催化Heck反应[J]. 催化学报, 2023, 46(3): 72-83.
[4]	翁雪霏, 杨双莉, 丁丁, 陈明树, 万惠霖. 宽波段原位红外吸收光谱在Pd/SiO₂和Cu/SiO₂催化剂上CO氧化中的应用[J]. 催化学报, 2022, 43(8): 2001-2009.
[5]	谢林峰, 刘轩, 黄凡洋, 梁嘉顺, 刘健云, 王谭源, 杨利明, 曹瑞国, 李箐. 通过金属间化合物PdBi纳米片调控Pd基催化剂电催化CO₂还原为甲酸盐[J]. 催化学报, 2022, 43(7): 1680-1686.
[6]	王凯, 林祥丰, 李倩, 刘䶮, 李灿. 钯(0)/铜(I)协同催化脱羧不对称4+2环加成反应合成四环香豆素[J]. 催化学报, 2022, 43(7): 1812-1817.
[7]	魏呵呵, 黎晓阳, 邓铂瀚, 郎嘉良, 黄雅, 华星宇, 乔奕达, 葛炳辉, 戈钧, 伍晖. Pd单原子/团簇高效催化铃木偶联反应[J]. 催化学报, 2022, 43(4): 1058-1065.
[8]	李振宇, 淮丽媛, 郝盼盼, 赵玺, 王永钊, 张炳森, 谌春林, 张建. 碳纳米管负载钯基催化剂催化氧化2,5-呋喃二甲醇合成2,5-呋喃二甲酸[J]. 催化学报, 2022, 43(3): 793-801.
[9]	张文彪, 石杨豪, 杨洋, 谭静雯, 高庆生. 电催化糠醛加氢反应中钯纳米晶的晶面效应[J]. 催化学报, 2022, 43(12): 3116-3125.
[10]	朱莉, 林翌阳, 刘康, Emiliano Cortés, 李红梅, 胡俊华, Akira Yamaguchi, 刘小良, Masahiro Miyauchi, 傅俊伟, 刘敏. CuPd催化剂调节中间反应能垒提高电催化CO₂生成二碳产物的选择性[J]. 催化学报, 2021, 42(9): 1500-1508.
[11]	王凯, 王彬力, 刘相慧, 樊红军, 刘龑, 李灿. 钯催化烯基苯并噁嗪酮基于内球型机理的线性和不对称烯丙基烷基化反应[J]. 催化学报, 2021, 42(7): 1227-1237.
[12]	李晶, 孙翔, 段永正, 贾冬梅, 李跃金, 王建国. 部分氧化碳化硅提高钯催化氧还原反应性能[J]. 催化学报, 2021, 42(6): 963-970.
[13]	赵东越, 杨岳溪, 高中楠, 尹萌欣, 田野, 张静, 姜政, 于晓波, 李新刚. 贫燃/富燃循环气氛下原位活化Pd负载钙钛矿催化剂促进NO_x还原消除[J]. 催化学报, 2021, 42(5): 795-807.
[14]	董春燕, 周燕, 塔娜, 刘雯璐, 李名润, 申文杰. 氧化铈形貌对Pd纳米粒子分散的影响[J]. 催化学报, 2021, 42(12): 2234-2241.
[15]	高明洋, 龚忠苗, 翁雪霏, 尚炜翔, 柴玉超, 戴卫理, 武光军, 关乃佳, 李兰冬. MFI分子筛限域空间内Pd催化剂上甲烷燃烧[J]. 催化学报, 2021, 42(10): 1689-1699.