电子修饰非晶态镍钨硼化物催化剂用于高效光热二氧化碳甲烷化-CSCIED科技核心评价数据库-手机版

电子修饰非晶态镍钨硼化物催化剂用于高效光热二氧化碳甲烷化

Electron-Tailored Amorphous Nickel-Tungsten Boride Catalysts for High-Efficiency Photothermal Carbon Dioxide Methanation

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DOI	10.1016/j.jcis.2025.139001
刊名	Journal of Colloid and Interface Science
年，卷(期)	2025, 702()
作者	杨乐, 刘蓉蓉, 梁军, 李莉,
作者单位	宁夏大学
摘要	对可持续利用二氧化碳（CO?）的迫切需求推动了光热催化作为太阳能驱动CO?甲烷化高效策略的发展。本文报道了一种非晶态镍钨硼化物（NiWB）催化剂，该催化剂在温和条件下无需外部加热即可实现CO?向甲烷（甲烷）的卓越转化。优化后的NiWB催化剂在全光谱光照（2.0 W cm? 2）下展现出19.32 mmol g? 1 h? 1 的高甲烷产率，选择性达92.50%，超过了大多数已报道的镍基催化剂。结构与电子表征表明，非晶态框架提供了丰富的不饱和活性位点，而钨的掺入增强了界面相互作用并调节了Ni位点的电子结构，促进了H?和CO?的活化。原位漫反射红外傅里叶变换光谱（DRIFS）分析证实了甲酸盐介导的反应路径，动力学研究表明光热协同作用相较于纯热催化显著降低了活化能。此外，非晶催化剂中稳定W-B键的形成抑制了结晶，提高了催化剂的耐久性。本研究凸显了非晶工程与电子调控在设计高效光热催化剂以实现CO?可持续利用方面的协同优势。
Abstract	The urgent need for sustainable carbon dioxide (CO2) utilization has driven the development of photothermal catalysis as an efficient strategy for solar-driven CO2 methanation. Herein, we report an amorphous nickel-tungsten boride (NiWB) catalyst that achieves exceptional conversion of CO2 to methane (CH4) under mild conditions without external heating. The optimized NiWB catalyst exhibits a remarkable CH4 production rate of 19.32 mmol g?1 h?1 with 92.50% selectivity under full-spectrum illumination (2.0 W cm?2), surpassing most reported Ni-based catalysts. Structural and electronic characterizations reveal that the amorphous framework provides abundant unsaturated active sites, while W incorporation enhances interfacial interactions and modulates the electronic structure of Ni sites, promoting H2 and CO2 activation. In situ Diffuse Reflectance Infrared Fourier Transform Spectroscopy (DRIFS) analysis confirms a formate-mediated reaction pathway, and kinetic studies demonstrate that photothermal synergy significantly reduces activation energy compared to pure thermal catalysis. Furthermore, the formation of stable W-B bonds in amorphous catalyst inhibits crystallization, improving catalyst durability. This work highlights the synergistic advantages of amorphous engineering and electronic modulation in designing efficient photothermal catalysts for sustainable CO2 valorization.
关键词	二氧化碳甲烷化；光热催化；非晶态催化剂；电子调制；镍钨硼化物
KeyWord	CO2 methanation; photothermal catalysis; amorphous catalyst; electron modulation; nickel-tungsten boride.
基金项目
页码	139001-139001

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相关文献

[1] F. Fresno, A. Iglesias-Juez, J.M. Coronado, Photothermal Catalytic CO? Conversion: Beyond Catalysis and Photocatalysis, Top. Curr. Chem., 381 (2023) 21.

[2] M. Bonchio, J. Bonin, O. Ishitani, T.-B. Lu, T. Morikawa, A.J. Morris, E. Reisner, D. Sarkar, F.M. Toma, M. Robert, Best practices for experiments and reporting in photocatalytic CO? reduction, Nat. Catal., 6 (2023) 657-665.

[3] K. Hashimoto, H. Habazaki, M. Yamasaki, S. Meguro, T. Sasaki, H. Katagiri, T. Matsui, K. Fujimura, K. Izumiya, N. Kumagai, E. Akiyama, Advanced materials for global carbon dioxide recycling, Mater. Sci. Eng. A, 304-306 (2001) 88-96.

[4] J. Ren, H. Lou, N. Xu, F. Zeng, G. Pei, Z. Wang, Methanation of CO/CO? for power to methane process: Fundamentals, status, and perspectives, J. Energy Chem., 80 (2023) 182-206.

[5] A. Mukhtar, S. Saqib, E. Agyekum-Oduro, J. Zhu, S. Wu, Conceptual unification of mechanism-guided catalyst design for CO? conversion to C? products in thermal and plasma catalysis, Appl. Phys. Rev., 12 (2025) 021302.

[6] A. Wang, C. Bozal-Ginesta, S.G. Hari Kumar, A. Aspuru-Guzik, G.A. Ozin, Designing materials acceleration platforms for heterogeneous CO? photo(thermal)catalysis, Matter., 6 (2023) 1334-1347.

[7] D. Mateo, J.L. Cerrillo, S. Durini, J. Gascon, Fundamentals and applications of photo-thermal catalysis, Chem. Soc. Rev., 50 (2021) 2173-2210.

[8] M.A. Panhwar, B. Guene Lougou, M. Rafique, W. Wang, M. Azeem, B. Geng, H. Zhang, A. Ghorbal, Y. Shuai, Synergistic co-catalyst strategies for photo-thermal CO? reduction into value-added fuels: A critical review on mechanisms, challenges, and future prospects, Fuel, 400 (2025) 135729.

[9] C. Preston-Herrera, S. Dadashi-Silab, D.G. Oblinsky, G.D. Scholes, E.E. Stache, Molecular Photothermal Conversion Catalyst Promotes Photocontrolled Atom Transfer Radical Polymerization, J. Am. Chem. Soc., 146 (2024) 8852-8857.

[10] Y. Xiong, X. Liu, Y. Hu, D. Gu, M. Jiang, Z. Tie, Z. Jin, Ag??Au cluster decorated mesoporous Co?O? for highly selective and efficient photothermal CO? hydrogenation, Nano Res., 15 (2022) 4965-4972.

[11] C. Xu, Q. Tang, W. Tu, L. Wang, Photon and phonon powered photothermal catalysis, Energy Environ. Sci., 17 (2024) 4461-4480.

[12] P. Sharma, A. Kumar, T. Wang, P. Dhiman, G. Sharma, G. Rana, Recent advances in photothermal assisted photocatalytic CO? reduction and H? production by semiconductor heterojunctions, J. Environ. Chem. Eng., 12 (2024) 114876.

[13] Y. Liu, A. Madanchi, A.S. Anker, L. Simine, V.L. Deringer, The amorphous state as a frontier in computational materials design, Nat. Rev. Mater., 10 (2025) 228-241.

[14] C. Hu, B. Li, K. Nie, Z. Wang, Y. Zhang, L. Yi, X. Hao, H. Zhang, S. Chong, Z. Liu, W. Huang, Ultrafast Tailoring Amorphous Zn?.??V?O? with Precision-Engineered Artificial Atomic-Layer 1T′-MoS? Cathode Electrolyte Interphase for Advanced Aqueous Zinc-Ion Batteries, Angew. Chem. Int. Ed., 64 (2025) e202413173.

[15] F. Ye, A. Ayub, R. Karimi, S. Wettig, J. Sanderson, K.P. Musselman, Defect-Rich MoSe? 2H/1T Hybrid Nanoparticles Prepared from Femtosecond Laser Ablation in Liquid and Their Enhanced Photothermal Conversion Efficiencies, Adv. Mater., 35 (2023) 2301129.

[16] C. Wei, X. Jin, C. Wu, A. Brozovic, W. Zhang, Carbon spheres with high photothermal conversion efficiency for photothermal therapy of tumor, Diam. Relat. Mater., 126 (2022) 109048.

[17] T. Feng, T. Zhao, N. Zhang, Y. Duan, L. Li, F. Wu, R. Chen, 2D Amorphous Mo-Doped CoB for Bidirectional Sulfur Catalysis in Lithium Sulfur Batteries, Adv. Funct. Mater., 32 (2022) 2202766.

[18] K. Mori, T. Taga, H. Yamashita, Isolated Single-Atomic Ru Catalyst Bound on a Layered Double Hydroxide for Hydrogenation of CO? to Formic Acid, ACS Catal., 7 (2017) 3147-3151.

[19] B. Wang, L. Wang, B. Guo, Y. Kong, F. Wang, Z. Jing, G. Qu, M. Mamoor, D. Wang, X. He, L. Kong, L. Xu, In Situ Electrochemical Evolution of Amorphous Metallic Borides Enabling Long Cycling Room-/Subzero-Temperature Sodium-Sulfur Batteries, Adv. Mater., 36 (2024) 2411725.

[20] J. He, S. Chang, H. Du, B. Jiang, W. Yu, Z. Wang, W. Chu, L. Han, J. Zhu, H. Li, Efficient hydrogenation of CO? to formic acid over amorphous NiRuB catalysts, J. CO? Util., 54 (2021) 101751.

[21] X. Wang, Z. Yao, X. Guo, Z. Yan, H. Ban, P. Wang, R. Yao, L. Li, C. Li, Modulating Electronic Interaction over Zr–ZnO Catalysts to Enhance CO? Hydrogenation to Methanol, ACS Catal., 14 (2024) 508-521.

[22] K.N. Woods, M.C. Thomas, G. Mitchson, J. Ditto, C. Xu, D. Kayal, K.C. Frisella, T. Gustafsson, E. Garfunkel, Y.J. Chabal, D.C. Johnson, C.J. Page, Nonuniform Composition Profiles in Amorphous Multimetal Oxide Thin Films Deposited from Aqueous Solution, ACS Appl. Mater. Interfaces, 9 (2017) 37476-37483.

[23] D. He, L. Cao, L. Feng, S. Li, Y. Feng, G. Li, Y. Zhang, J. Li, J. Huang, Dual modulation of morphology and electronic structures of VN@C electrocatalyst by W doping for boosting hydrogen evolution reaction, Chin. Chem. Lett., 33 (2022) 4781-4785.

[24] S. Liu, Y. Wang, H. Zhao, H. Li, W. Xiao, Z. Xiao, G. Xu, D. Chen, Z. Wu, L. Wang, Amorphous W-doped iron phosphide with superhydrophilic surface to boost water-splitting under large current density, Chem. Eng. J., 496 (2024) 153956.

[25] Y. Zhou, P. Zheng, F. Wang, F. Gu, W. Xu, Q. Lu, T. Zhu, Z. Zhong, G. Xu, F. Su, NiO@Ni nanoparticles embedded in N-doped carbon for efficient photothermal CO? methanation coupled with H?O splitting, Nano Res., 17 (2024) 2283-2290.

[26] Y. Luo, H. Huang, C. Li, K. Ren, W. Dou, Highly Efficient and Selective Photothermal Catalytic CO? Reduction to CH? Using the CoNi Bimetallic-Modified Gd?O?&Co?O? Nanocomposite, ACS Sustainable Chem. Eng., 12 (2024) 15682-15695.

[27] Z. Yuan, B. Zhang, X. Zhu, S. Wang, W. Sun, B. Huang, Z. Jiang, Y. Dai, Z. Wang, W. Wei, X. Tai, Y.-Q. Lan, In situ Doping Coupling With Vacancy Regulation Induced Strong Metal-Support Interaction in Ni/CaTiO? to Boost Supercharged Photothermal CO? Methanation, Adv. Funct. Mater., 35 (2025) 2503531.

[28] C. Guo, Y. Tang, Z. Yang, T. Zhao, J. Liu, Y. Zhao, F. Wang, Reinforcing the Efficiency of Photothermal Catalytic CO? Methanation through Integration of Ru Nanoparticles with Photothermal MnCo?O? Nanosheets, ACS Nano, 17 (2023) 23761-23771.

[29] F. Raziq, C. Feng, M. Hu, S. Zuo, M.Z. Rahman, Y. Yan, Q.-H. Li, J. Gascon, H. Zhang, Isolated Ni Atoms Enable Near-Unity CH? Selectivity for Photothermal CO? Hydrogenation, J. Am. Chem. Soc., 146 (2024) 21008-21016.

[30] C. Guo, L. Wang, Y. Tang, Z. Yang, Y. Zhao, Y. Jiang, X. Wen, F. Wang, Enhanced Photo-Thermal CO? Methanation with Tunable Ru?Ni??? Catalytic Sites: Alloying Beyond Pure Ru,Adv. Funct. Mater., 35 (2025) 2414931.

[31] T. Dong, X. Liu, Z. Tang, H. Yuan, D. Jiang, Y. Wang, Z. Liu, X. Zhang, S. Huang, H. Liu, L. Zhao, W. Zhou, Ru decorated TiO? nanoparticles via laser bombardment for photothermal co-catalytic CO? hydrogenation to methane with high selectivity, Appl. Catal. B Environ., 326 (2023) 122176.

[32] C. Liu, Y. Zhang, H. Kong, Z. Chen, Y. Zhang, H. Liu, W. Gao, K. Zhou, L. Zhao, W. Xia, X. Liu, W. Zhou, Ru-decorated defective tantalum oxide via laser synthesis for efficient photothermal CO? methanation, Chin. Chem. Lett., 37 (2025) 111345.

[33] Z. Yang, Z.-Y. Wu, Z. Lin, T. Liu, L. Ding, W. Zhai, Z. Chen, Y. Jiang, J. Li, S. Ren, Z. Lin, W. Liu, J. Feng, X. Zhang, W. Li, Y. Yu, B. Zhu, F. Ding, Z. Li, J. Zhu, Optically selective catalyst design with minimized thermal emission for facilitating photothermal catalysis, Nat. Commun., 15 (2024) 7599.

[34] J. Chen, Y. Ren, Y. Fu, Y. Si, J. Huang, J. Zhou, M. Liu, L. Duan, N. Li, Integration of Co Single Atoms and Ni Clusters on Defect-Rich ZrO? for Strong Photothermal Coupling Boosts Photocatalytic CO? Reduction, ACS Nano, 18 (2024) 13035-13048.

[35] H. Wang, M.S. Bootharaju, J.H. Kim, Y. Wang, K. Wang, M. Zhao, R. Zhang, J. Xu, T. Hyeon, X. Wang, S. Song, H. Zhang, Synergistic Interactions of Neighboring Platinum and Iron Atoms Enhance Reverse Water–Gas Shift Reaction Performance, J. Am. Chem. Soc., 145 (2023) 2264-2270.

[36] A. Takeuchi, A. Inoue, Classification of Bulk Metallic Glasses by Atomic Size Difference, Heat of Mixing and Period of Constituent Elements and Its Application to Characterization of the Main Alloying Element, Mater. Trans., 46 (2005) 2817-2829.

[37] A. Inoue, Stabilization of metallic supercooled liquid and bulk amorphous alloys, Acta Mater., 48 (2000) 279-306.

[38] X. Yin, Q. Wang, D. Duan, S. Liu, Y. Wang, Amorphous NiB alloy decorated by Cu as the anode catalyst for a direct borohydride fuel cell, Int. J. Hydrogen Energy, 44 (2019) 10971-10981.

[39] Q. Wang, L. Li, R. Liu, P. Wang, Y. Wang, J. Liang, An Efficient Strategy for Tailoring Interfacial Charge Transfer Pathway on Semiconductor Photocatalysts: A Case of (BiFeO?)?(SrTiO?)???/Mn?O?, Adv. Funct. Mater., 34 (2024) 2408420.

[40] S. Mo, S. Li, J. Zhou, X. Zhao, H. Zhao, X. Zhou, Y. Fan, Z. Zhu, B. Li, Q. Xie, W. Si, Y. Chen, D. Ye, J. Li, Asymmetric Interaction between Carbon and Ni-Cluster in Ni–C–In Photothermal Catalysts for Point-Concentrated Solar-Driven CO? Reverse Water–Gas Shift Reaction, ACS Catal., 15 (2025) 2796-2808.

[41] S. Meng, M. Sun, P. Zhang, C. Zhou, C. He, H. Zhang, Y. Liu, Z. Xiong, P. Zhou, B. Lai, Metal Borides as Excellent Co-Catalysts for Boosted and Long-Lasting Fenton-like Reaction: Dual Co-Catalytic Centers of Metal and Boron, Environ. Sci. Technol., 57 (2023) 12534-12545.

[42] X. Liu, X. Wang, Y. Si, F. Han, Glass-Forming Ability and Thermal Properties of Al??Fe??.?V??.?X?(X = Zr, Nb, Ni) Amorphous Alloys via Minor Alloying Additions, Nanomaterials., 11 (2021) 488.

[43] W.-L. Dai, M.-H. Qiao, J.-F. Deng, XPS studies on a novel amorphous Ni–Co–W–B alloy powder, Appl. Surf. Sci., 120 (1997) 119-124.

[44] Y. Tang, H. Wang, C. Guo, Z. Yang, T. Zhao, J. Liu, Y. Jiang, W. Wang, Q. Zhang, D. Wu, Y. Zhao, X.-D. Wen, F. Wang, Ruthenium–Cobalt Solid-Solution Alloy Nanoparticles for Enhanced Photopromoted Thermocatalytic CO? Hydrogenation to Methane, ACS Nano, 18 (2024) 11449-11461.

[45] J. He, P. Lyu, B. Jiang, S. Chang, H. Du, J. Zhu, H. Li, A novel amorphous alloy photocatalyst (NiB/In?O?) composite for sunlight-induced CO? hydrogenation to HCOOH, Appl. Catal. B Environ., 298 (2021) 120603.

[46] C. Wang, Y. Lu, Y. Zhang, H. Fu, S. Sun, F. Li, Z. Duan, Z. Liu, C. Wu, Y. Wang, H. Sun, Z. Yan, Ru-based catalysts for efficient CO? methanation: Synergistic catalysis between oxygen vacancies and basic sites, Nano Res., 16 (2023) 12153-12164.

[47] L.O. Paulista, A.F.P. Ferreira, A.E. Rodrigues, R.J.E. Martins, R.A.R. Boaventura, V.J.P. Vilar, T.F.C.V. Silva, Solar thermo-photocatalytic methanation using a bifunctional RuO?:TiO?/Z13X photocatalyst/adsorbent material for efficient CO? capture and conversion, J. Environ. Chem. Eng., 12 (2024) 112418.

[48] R. Ye, L. Ma, X. Hong, T.R. Reina, W. Luo, L. Kang, G. Feng, R. Zhang, M. Fan, R. Zhang, J. Liu, Boosting Low-Temperature CO? Hydrogenation over Ni-based Catalysts by Tuning Strong Metal-Support Interactions, Angew. Chem. Int. Ed., 63 (2024) e202317669.

引用本文

杨乐, 刘蓉蓉, 梁军*, 李莉*. 电子修饰非晶态镍钨硼化物催化剂用于高效光热二氧化碳甲烷化 [J]. Journal of Colloid and Interface Science. 2025; 702; (). 139001 - 139001.

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