Inorganic Chemicals Industry ›› 2024, Vol. 56 ›› Issue (1): 23-32.doi: 10.19964/j.issn.1006-4990.2023-0225
• Reviews and Special Topics • Previous Articles Next Articles
Research progress of synergistic effect catalytic reforming of methane and carbon dioxide
HU Mingliang(
), ZHOU Wei, LI Bin, LAI Xiaoling
- CenerTech Tianjin Chemical Research and Design Institute Co. Ltd. Tianjin 300131,China
-
Received:2023-04-21Online:2024-01-10Published:2024-01-18
CLC Number:
Cite this article
HU Mingliang, ZHOU Wei, LI Bin, LAI Xiaoling. Research progress of synergistic effect catalytic reforming of methane and carbon dioxide[J]. Inorganic Chemicals Industry, 2024, 56(1): 23-32.
share this article
Fig.1
Schematic diagram of Fe-Co synergistic catalysis[29]"
Fig.1
Fig.2
Schematic representation of MEO thin layer-confined and stabilized Ni catalyst and reference sample[33]"
Fig.2
Fig.3
Reaction pathways and total rates of DRM reaction on Co(111) and Co(211) as a function of temperature[35]"
Fig.3
Fig.4
Proposed reaction mechanism over 10Ni1Co@ADM-0.1 catalyst[40]"
Fig.4
Fig.5
Illustration of confined In-Ni alloy catalyst forreforming of methane and carbon dioxide [53]"
Fig.5
Fig.6
Top views and side views of transition-state geometries of CH4 activation(a,b,c,d) and intermediategeometries of CH3 and H(e,f,g,h) formed on Ni1 and Ru1 sites on CeO2[56]"
Fig.6
| 1 | FRANCKE R, SCHILLE B, ROEMELT M.Homogeneously catalyzed electroreduction of carbon dioxide:methods,mechanisms,and catalysts[J].Chemical Reviews,2018,118(9):4631-4701. |
| 2 | LU Yao, KANG Li, GUO Dan,et al.Double-site doping of a V promoter on Nix -V-MgAl catalysts for the DRM reaction:Simultaneous effect on CH4 and CO2 activation[J].ACS Catalysis,2021,11(14):8749-8765. |
| 3 | JIANG Xiao, NIE Xiaowa, GUO Xinwen,et al.Recent advances in carbon dioxide hydrogenation to methanol via heterogeneous catalysis[J].Chemical Reviews,2020,120(15):7984-8034. |
| 4 | FORS S A, MALAPIT C A.Homogeneous catalysis for the conversion of CO2,CO,CH3OH,and CH4 to C2+ chemicals via C—C bond formation[J].ACS Catalysis,2023,13(7):4231-4249. |
| 5 | FLORIAN J, COLE J M.Analyzing structure-activity variations for Mn-carbonyl complexes in the reduction of CO2 to CO[J].Inorganic Chemistry,2023,62(1):318-335. |
| 6 | ADAMSON T T, KELLEY S P, BERNSKOETTER W H.Iron-mediated C—C bond formation via reductive coupling with carbon dioxide[J].Organometallics,2020,39(19):3562-3571. |
| 7 | VICHOU E, LI Yun, GOMEZ-MINGOT M,et al.Imidazolium- and pyrrolidinium-based ionic liquids as cocatalysts for CO2 electroreduction in model molecular electrocatalysis[J].The Journal of Physical Chemistry C,2020,124(43):23764-23772. |
| 8 | HU Mingliang, LIU Jiahao, SONG Shaojia,et al.Ultra-thin two-dimensional trimetallic metal-organic framework for photocatalytic reduction of CO2 [J].ACS Catalysis,2022,12(5):3238-3248. |
| 9 | WANG Weiwei, SONG Shaojia, WANG Ping,et al.Chemical bonding of g-C3N4/UiO-66(Zr/Ce) from Zr and Ce single atoms for efficient photocatalytic reduction of CO2 under visible light[J].ACS Catalysis,2023,13(7):4597-4610. |
| 10 | YANG Jinman, YANG Zhengrui, YANG Kefen,et al.Indium-based ternary metal sulfide for photocatalytic CO2 reduction application[J].Chinese Journal of Catalysis,2023,44:67-95. |
| 11 | JIANG Yuheng, ZHAO Wenshi, LI Siyang,et al.Elevating photooxidation of methane to formaldehyde via TiO2 crystal phase engineering[J].Journal of the American Chemical Society,2022,144(35):15977-15987. |
| 12 | 黄兴,赵博宇,张昊,等.聚集辐照下甲烷水蒸气重整制氢过程参数研究[J].石油与天然气化工,2021,50(4):58-65. |
| HUANG Xing, ZHAO Boyu, ZHANG Hao,et al.Parameters research for hydrogen production of methane steam reforming under concentrated radiation[J].Chemical Engineering of Oil & Gas,2021,50(4):58-65. | |
| 13 | YOON Y, YOU H M, KIM H J,et al.Computational catalyst design for dry reforming of methane:A review[J].Energy & Fuels,2022,36(17):9844-9865. |
| 14 | LIN Shiru, TRISTAN J B, WANG Yang,et al.Dry reforming of methane on doped Ni nanoparticles:Feature-assisted optimizations and ranking of doping metals for direct activations of CH4 and CO2 [J].Nano Research,2022,15(10):9670-9682. |
| 15 | HUANG Weiqiao, WEI Changgeng, LI Yi,et al.The role of Mo species in Ni-Mo catalysts for dry reforming of methane[J].Physical Chemistry Chemical Physics,2022,24(35):21461-21469. |
| 16 | GUHAROY U, REINA T R, LIU Jian,et al.A theoretical overview on the prevention of coking in dry reforming of methane using non-precious transition metal catalysts[J].Journal of CO2 Utilization,2021,53:101728. |
| 17 | MANAVI N, LIU Bin.Molecular mechanisms of methane dry reforming on Co3Mo3N catalyst with dual sites[J].Catalysis Science & Technology,2021,11(11):3724-3736. |
| 18 | GONZÁLEZ-CASTAÑO M, LE SACHÉ E, BERRY C,et al.Nickel phosphide catalysts as efficient systems for CO2 upgrading via dry reforming of methane[J].Catalysts,2021,11(4):446. |
| 19 | KULANDAIVALU T, MOHAMED A R, ALI K A,et al.Photocatalytic carbon dioxide reforming of methane as an alternative approach for solar fuel production:A review[J].Renewable and Sustainable Energy Reviews,2020,134:110363. |
| 20 | WANG Lei, WANG Fagen.Design strategy,synthesis,and mechanism of Ni catalysts for methane dry reforming reaction:Recent advances and future perspectives[J].Energy & Fuels,2022,36(11):5594-5621. |
| 21 | QI Ronghua, AN Lei, GUO Yu,et al. In situ fabrication of ultrasmall Ni nanoparticles from Ni(OH)2 precursors for efficient CO2 reforming of methane[J].Industrial & Engineering Chemistry Research,2022,61(1):198-206. |
| 22 | ZHANG Xiaoyu, DENG Jiang, LAN Tianwei,et al.Promoting methane dry reforming over Ni catalysts via modulating surface electronic structures of BN supports by doping carbon[J].ACS Catalysis,2022,12(22):14152-14161. |
| 23 | WANG Dingdi, LITTLEWOOD P, MARKS T J,et al.Coking can enhance product yields in the dry reforming of methane[J].ACS Catalysis,2022,12(14):8352-8362. |
| 24 | LITTLEWOOD P, WEITZ E, MARKS T J,et al.Kinetic isoconversion loop catalysis:A reactor operation mode to investigate slow catalyst deactivation processes,with Ni/Al2O3 for the dry reforming of methane[J].Industrial & Engineering Chemistry Research,2019,58(7):2481-2491. |
| 25 | ZHAO Ling, LUO Yicong, XIAO Junzhe,et al.Stereodivergent synthesis of allenes with α,β-adjacent central chiralities empowered by synergistic Pd/Cu catalysis[J].Angewandte Chemie International Edition,2023,62(9):e202218146. |
| 26 | XIAO Zeyu, SUN Panpan, QIAO Zelong,et al.Atomically dispersed Fe-Cu dual-site catalysts synergistically boosting oxygen reduction for hydrogen fuel cells[J].Chemical Engineering Journal,2022,446:137112. |
| 27 | GUO Yalin, HUANG Yike, ZENG Bin,et al.Photo-thermo semi-hydrogenation of acetylene on Pd1/TiO2 single-atom catalyst[J].Nature Communications,2022,13:2648. |
| 28 | YI Jundong, GAO Xiaoping, ZHOU Huang,et al.Design of Co-Cu diatomic site catalysts for high-efficiency synergistic CO2 electroreduction at industrial-level current density[J].Angewandte Chemie International Edition,2022,61(47):e202212329. |
| 29 | HAN Qinglin, ZHAO Ximeng, LUO Yuhong,et al.Synergistic binary Fe-Co nanocluster supported on defective tungsten oxide as efficient oxygen reduction electrocatalyst in zinc-air battery[J].Advanced Science,2022,9(4):2104237. |
| 30 | LI Zhenxing, HU Mingliang, LIU Jiahao,et al.Mesoporous silica stabilized MOF nanoreactor for highly selective semi-hydrogenation of phenylacetylene via synergistic effect of Pd and Ru single site[J].Nano Research,2022,15(3):1983-1992. |
| 31 | ZHONG Dichang, GONG Yunnan, ZHANG Chao,et al.Dinuclear metal synergistic catalysis for energy conversion[J].Chemical Society Reviews,2023,52(9):3170-3214. |
| 32 | VAKILI R, GHOLAMI R, STERE C E,et al.Plasma-assisted catalytic dry reforming of methane(DRM) over metal-organic frameworks(MOFs)-based catalysts[J].Applied Catalysis B:Environmental,2020,260:118195. |
| 33 | HE Lei, LI Mingrun, LI Wencui,et al.Robust and coke-free Ni catalyst stabilized by 1~2 nm-thick multielement oxide for methane dry reforming[J].ACS Catalysis,2021,11(20):12409-12416. |
| 34 | AKRI M, ZHAO Shu, LI Xiaoyu,et al.Atomically dispersed nickel as coke-resistant active sites for methane dry reforming[J].Nature Communications,2019,10:5181. |
| 35 | CHEN Shuyue, ZAFFRAN J, YANG Bo.Dry reforming of methane over the cobalt catalyst:Theoretical insights into the reaction kinetics and mechanism for catalyst deactivation[J].Applied Catalysis B:Environmental,2020,270:118859. |
| 36 | JOSÉ-ALONSO D SAN, ILLÁN-GÓMEZ M J, ROMÁN-MARTÍNEZ M C.K and Sr promoted Co alumina supported catalysts for the CO2 reforming of methane[J].Catalysis Today,2011,176(1):187-190. |
| 37 | 莫文龙,马凤云,郝世豪,等.介孔Al2O3的制备及其在CO2-CH4重整镍基催化剂中的应用研究[J].天然气化工(C1化学与化工),2014,39(5):16-21. |
| MO Wenlong, MA Fengyun, HAO Shihao,et al.Preparation of ordered mesoporous Al2O3 and its application in Ni-based catalysts for CH4/CO2 reforming[J].Natural Gas Chemical Industry,2014,39(5):16-21. | |
| 38 | 张小平.制备方式对Ni-ZrO2催化剂在甲烷二氧化碳重整中催化性能的影响[J].现代化工,2020,40(1):189-193. |
| ZHANG Xiaoping.Influence of preparation methods on catalytic property of Ni-ZrO2 catalyst in CO2 reforming of CH4 [J].Modern Chemical Industry,2020,40(1):189-193. | |
| 39 | 万吉纯,朱孔涛,翁维正,等.氨辅助浸渍法制备抗烧结Ni/SiO2催化剂及其甲烷二氧化碳重整反应的性能[J].厦门大学学报(自然科学版),2019,58(5):651-660. |
| WAN Jichun, ZHU Kongtao, WENG Weizheng,et al.Preparation of sinter-resistant Ni/SiO2 catalysts using ammonia-assisted impregnation method and its performance in CO2 reforming of methane[J].Journal of Xiamen University(Natural Science),2019,58(5):651-660. | |
| 40 | LIANG Defang, WANG Yishuang, CHEN Mingqiang,et al.Dry reforming of methane for syngas production over attapulgite-derived MFI zeolite encapsulated bimetallic Ni-Co catalysts[J].Applied Catalysis B:Environmental,2023,322:122088. |
| 41 | DENG Jiang, GAO Min, HASEGAWA J,et al.Unravelling the anomalous coking-resistance over boron nitride supported Ni catalysts for dry reforming of methane[J].CCS Chemistry,2022.Doi:10.31635/ccschem.022.202202342. |
| 42 | ZHANG Xianhua, PEI Chunlei, CHANG Xin,et al.FeO6 octahedral distortion activates lattice oxygen in perovskite ferrite for methane partial oxidation coupled with CO2 splitting[J].Journal of the American Chemical Society,2020,142(26):11540-11549. |
| 43 | ZHAO Tingting, ZHAO Jiankang, TAO Xuyingnan,et al.Highly active and thermostable submonolayer La(NiCo)OΔ catalyst stabilized by a perovskite LaCrO3 support[J].Communications Chemistry,2022,5:70. |
| 44 | FENG Chao, BI Yuxi, CHEN Chong,et al.Urea-H2O2 defect engineering of δ-MnO2 for propane photothermal oxidation:Structure-activity relationship and synergetic mechanism determination[J].Journal of Colloid and Interface Science,2023,641:48-58. |
| 45 | LIU Jingjing, SUN Shengnan, LIU Jiang,et al.Achieving high-efficient photoelectrocatalytic degradation of 4-chlorophenol via functional reformation of titanium-oxo clusters[J].Journal of the American Chemical Society,2023,145(11):6112-6122. |
| 46 | LI Zhenxing, YU Chengcheng, KANG Yikun,et al.Ultra-small hollow ternary alloy nanoparticles for efficient hydrogen evolution reaction[J].National Science Review,2021,8(7):nwaa204. |
| 47 | LI Zhenxing, YU Chengcheng, WEN Yangyang,et al.Mesoporous hollow Cu-Ni alloy nanocage from core-shell Cu@Ni nanocube for efficient hydrogen evolution reaction[J].ACS Catalysis,2019,9(6):5084-5095. |
| 48 | LI Zhenxing, MA Zhengzheng, WEN Yangyang,et al.Copper nanoflower assembled by sub-2 nm rough nanowires for efficient oxygen reduction reaction:High stability and poison resistance and density functional calculations[J].ACS Applied Materials & Interfaces,2018,10(31):26233-26240. |
| 49 | WANG Jiyang, FU Yu, KONG Wenbo,et al.Investigation of atom-level reaction kinetics of carbon-resistant bimetallic NiCo-reforming catalysts:Combining microkinetic modeling and density functional theory[J].ACS Catalysis,2022,12(8):4382-4393. |
| 50 | REZAEI R, MORADI G, SHARIFNIA S.Dry reforming of methane over Ni-Cu/Al2O3 catalyst coatings in a microchannel reactor:Modeling and optimization using design of experiments[J].Energy & Fuels,2019,33(7):6689-6706. |
| 51 | WANG Lei, LI Dalin, KOIKE M,et al.Catalytic performance and characterization of Ni-Fe catalysts for the steam reforming of tar from biomass pyrolysis to synthesis gas[J].Applied Catalysis A:General,2011,392(1/2):248-255. |
| 52 | HUANG Tao, HUANG Wei, HUANG Jian,et al.Methane reforming reaction with carbon dioxide over SBA-15 supported Ni-Mo bimetallic catalysts[J].Fuel Processing Technology,2011,92(10):1868-1875. |
| 53 | LIU Wenming, LI Le, LIN Sixue,et al.Confined Ni-In intermetallic alloy nanocatalyst with excellent coking resistance for methane dry reforming[J].Journal of Energy Chemistry,2022,65:34-47. |
| 54 | LI Haocheng, HAO Cong, TIAN Jingqing,et al.Ultra-durable Ni-Ir/MgAl2O4 catalysts for dry reforming of methane enabled by dynamic balance between carbon deposition and elimination[J].Chem Catalysis,2022,2(7):1748-1763. |
| 55 | SHOJI S, MOHD NAJIB A S BIN, YU Minwen,et al.Charge partitioning by intertwined metal-oxide nano-architectural networks for the photocatalytic dry reforming of methane[J].Chem Catalysis,2022,2(2):321-329. |
| 56 | TANG Yu, WEI Yuechang, WANG Ziyun,et al.Synergy of single-atom Ni1 and Ru1 sites on CeO2 for dry reforming of CH4 [J].Journal of the American Chemical Society,2019,141(18):7283-7293. |
| 57 | WANG Ye, LI Li, LI Guiying,et al.Synergy of oxygen vacancies and Ni0 species to promote the stability of a Ni/ZrO2 catalyst for dry reforming of methane at low temperatures[J].ACS Catalysis,2023,13(10):6486-6496. |
| 58 | ZHANG Xiao, XU Yao, LIU Yang,et al.A novel Ni-MoCx Oy interfacial catalyst for syngas production via the chemical looping dry reforming of methane[J].Chem,2023,9(1):102-116. |
| 59 | SHOJI S, PENG Xiaobo, YAMAGUCHI A,et al.Photocatalytic uphill conversion of natural gas beyond the limitation of thermal reaction systems[J].Nature Catalysis,2020,3(2):148-153. |
| [1] | WANG Ting, ZHANG Wenwen, MAO Qing, LÜ Li, LIU Changzhen. Research progress of catalytic system and materials for electrocatalytic reduction of carbon dioxide to ethanol [J]. Inorganic Chemicals Industry, 2024, 56(7): 1-10. |
| [2] | LIU Min, HUANG Xiu, ZHANG Liyuan. Research progress of S-type heterojunction photocatalysts [J]. Inorganic Chemicals Industry, 2024, 56(7): 18-27. |
| [3] | SHEN Haiyan, LI Fangqin, REN Jianxing, WU Jiang, GUAN Zhenzhen, PAN Weiguo. Research progress on chemical absorption method for capturing carbon dioxide [J]. Inorganic Chemicals Industry, 2024, 56(5): 11-19. |
| [4] | DENG Yinxiang, CHEN Chaoyi, WANG Shiyu, GAO Yingxue, PENG Shuang. Effect of cell voltage on electrochemical conversion of CO2 to carbon materials in CaCl2 based molten salt [J]. Inorganic Chemicals Industry, 2024, 56(1): 40-46. |
| [5] | MI Xiaotong, LI Xiaoguo, CHANG Yang, ZHANG Yongkun, LI Yongheng, CAO Hui, HOU Zhanggui. Collaborative construction of nanoscale ZSM-5 aggregates by crystal seeds and templates [J]. Inorganic Chemicals Industry, 2023, 55(6): 130-135. |
| [6] | WU Taolong, ZHANG Shengjiang, LIU Jinyang, HONG Xiaobo, LI Limin, QIN Xiaoyu, TAN Xiaoying, ZHOU Yan. Research progress of bimetallic-organic frameworks materials [J]. Inorganic Chemicals Industry, 2023, 55(6): 8-17. |
| [7] | XU Chunhui, WANG Feng, LING Changjian, WANG Zirui, TANG Zhongfeng. Research progress of CO2 capture by metal oxides modified by molten salts [J]. Inorganic Chemicals Industry, 2023, 55(5): 1-7. |
| [8] | JI Hongfeng, LI Canhua, DU Gang, ZHANG Yongzhu, XU Wenzhen, LI Minghui. Research progress of preparation and sintering resistance of calcium-based CO2 trapping materials from solid waste sources [J]. Inorganic Chemicals Industry, 2023, 55(3): 28-35. |
| [9] | LI Songhong,ZHOU Songhua,ZHAO Aiming,DONG Wenyan,JIANG Chunyan,CAO Yang,AO Xianquan. Study on catalytic gasification reaction of distillers′grains under H2O/CO2 atmosphere [J]. Inorganic Chemicals Industry, 2023, 55(2): 132-140. |
| [10] | YAN Shuo,YU Haibin,CHEN Zan. Technology development status of carbon dioxide removal from natural gas by membrane process [J]. Inorganic Chemicals Industry, 2022, 54(5): 38-46. |
| [11] | LI Xiangyang,LIU Ziwei,LI Keyan,GUO Xinwen. Study on preparation and performance of FeMn-MOF/CN heterojunction photo-Fenton catalyst [J]. Inorganic Chemicals Industry, 2022, 54(12): 126-132. |
| [12] | LI Jiahui,WANG Huan,LI Keyan,GUO Xinwen. Study on photocatalytic CO2 reduction performance of Co doped polymeric carbon nitride [J]. Inorganic Chemicals Industry, 2022, 54(11): 124-130. |
| [13] | Li Yiyi,Sun Qiaoyi,Ma Linge,Zhuo Jinde,Song Weiguo. Study on mineralization-desorption and regeneration of post-CO2 capture by glycine salt [J]. Inorganic Chemicals Industry, 2021, 53(2): 38-41. |
| [14] | Zhang Zheng,Wang Shaohua,Zhao Yaxu,Hua Zhongqiu,Tian Xuemin,Wu Yi. Study on gas sensitivity of HZSM5 zeolite film combined with SnO2 for methane [J]. Inorganic Chemicals Industry, 2021, 53(2): 105-109. |
| [15] | ZHOU Wei,YU Haibin,MA Xinbin. Oxidative dehydrogenation of ethane with carbon dioxide to ethylene over Cr/SSZ-13 catalyst [J]. Inorganic Chemicals Industry, 2021, 53(12): 43-48. |
| Viewed | ||||||
|
Full text |
|
|||||
|
Abstract |
|
|||||
|
||