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37. |
Tailoring lewis acidity of metal oxides on nickel to boost electrocatalytic hydrogen evolution in neutral electrolyteLin-Lin Wang,§ Xiao-Ran Wang,§ Hong-Juan Wang,§ Chong Zhang,§ Jing-Jing Li, Guo-Jin Feng, Xuan-Xuan Cheng, Xue-Rong Qin, Zi-You Yu,* and Tong-Bu Lu*J. Am. Chem. Soc., 2025, 147, 7555−7563. LINK |
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36. |
Boosting the durability of RuO2 via confinement effect for proton exchange membrane water electrolyzerWen-Xing Zheng†, Xuan-Xuan Cheng†, Ping-Ping Chen†, Lin-Lin Wang, Ying Duan, Guo-Jin Feng, Xiao-Ran Wang, Jing-Jing Li, Chao Zhang, Zi-You Yu* , and Tong-Bu Lu*Nat. Commun., 2025, 16, 337. LINK |
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35. |
Sun-simulated-driven production of high-purity methanol from carbon dioxideJiqing Jiao*, Yanbin Ma, Xiaoqian Han, Awu Ergu, Chao Zhang, Pingping Chen, Wei Liu, Qiquan Luo, Zhaolin Shi, Han Xu, Chen Chen, Yaguang Li*, and Tong-Bu Lu*Nat. Commun., 2025, 16, 857. LINK |
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34. |
Hydrogen-bonded organic frameworks for photocatalytic synthesis of hydrogen peroxideJi-Hong Zhang, Zhao-Ming Ge, Juan Wang, Di-Chang Zhong* & Tong-Bu LuNat. Commun., 2025, 16, 2448. LINK |
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33. |
Electroreduction of diluted CO2 to multicarbon products with high carbon utilization at 800 mA cm-2 in strongly acidic media Xue-Rong Qin†, Jing-Jing Li†, Lin-Lin Wang†, Guo-Jin Feng, Huan Liu, Zuo-Tao Yang, Xuan-Xuan Cheng, Chao Zhang, Zi-You Yu*, and Tong-Bu Lu* Nat. Commun., 2025, 16, 4447. LINK |
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32. |
MOF-based dual-layer pickering emulsion: molecular-level gating of water delivery at water-oil interface for efficient photocatalytic hydrogenation using H2O as a hydrogen sourceKuo Yuan,* Ying Zhang, Zhuang Yan, Qinbai Yun, Tianqun Song, Jun Guo, Jie Feng, Zheng Chen, Xiaotao Zhang, Zhiyong Tang, Wenping Hu, Tongbu Lu*Angew. Chem. Int. Ed., 2025, e202421341. LINK |
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31. |
Lattice Hydrogen Participation and Mass Transport Acceleration Improve CO2 Electroreduction to C2 ProductsHe Zhang+, Si-meng Liu+, Chao Zhang+, Wei Liu, Hong-liang Dong, Zhao-lin Shi, Han Xu, Jin-biao Liu, Ding-sheng Wang, Ji-qing Jiao,* Ming-bin Gao,* and Tong-bu Lu* Angew. Chem. Int. Ed., 2025, e18519. LINK |
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30. |
π–π Stacking as Electron-Transfer Channels in Hydrogen-Bonded Organic Frameworks for Boosting PhotocatalysisJian-Hua Mei+, Ya-Ru Zeng+, Yun-Nan Gong, Wen-Jie Shi, Di-Chang Zhong,* and Tong-Bu LuAngew. Chem. Int. Ed., 2025, 64, e202507332. LINK |
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29. |
Chlorine Radical-Mediated Photocatalytic C-C Coupling of Methanol to Ethylene Glycol with Near-Unity SelectivityGuang-Xing Dong, Meng-Ran Zhang, Su-Xian Yuan, Min Zhang,* and Tong-Bu Lu*Angew. Chem. Int. Ed., 2025, 64, e202510993 (Hot Paper). LINK |
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28. |
Modulating the chromophores of metal-covalent organic frameworks for boosting low-concentration CO2 photoreductionChong-Jiu Lu, Ji-Hong Zhang, Jian-Hua Mei, Yun-Nan Gong,* Tong-Bu Lu, and Di-Chang Zhong*Angew. Chem. Int. Ed., 2025, 64, e202505292. LINK |
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27. |
Unlocking one-step two-electron oxygen reduction via metalloid boron-modified Zn3In2S6 for efficient H2O2 photosynthesisJi-Li Zhou, Yan-Fei Mu,* Meng Qiao, Meng-Ran Zhang, Su-Xian Yuan, Min Zhang,* and Tong-Bu Lu*Angew. Chem. Int. Ed., 2025, e202506963. LINK |
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26. |
Self-photosensitizing cobalt complexes for photocatalytic CO2 reduction coupled with CH3OH oxidationJi-Hong Zhang+, Zhao-Ming Ge+, Di-Chang Zhong,* Jing-Lin Zuo, Marc Robert,* and Tong-Bu Lu*Angew. Chem. Int. Ed., 2025, e202506060. LINK |
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25. |
Gram-Scale Green-Synthesis of High Purity Pinacols and Amides by Continuous Tandem Photocatalysis via a Negative Carbon Emission ProcessXiao-Liang Ma, Wen-Xiong Shi, Song Guo,* Qiu-Ping Zhao, Wenbin Lin, Tong-Bu Lu,* and Zhi-Ming Zhang*Adv. Mater., 2025, 2506133. LINK |
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24. |
Precise synthesis of dual-atom catalysts for better understanding the enhanced catalytic performance and synergistic mechanismDi-Chang Zhong, Yu-Chen Wang, Mei Wang, and Tong-Bu Lu*Acc. Chem. Res., 2025, 58, 1379−1391. LINK |
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23. |
Breaking the symmetry of dual-atom catalysts enables efficient electrocatalytic CO2 reduction over ultra-wide potential windowMei Wang +*, Yan Yan+, Hong-Juan Wang+, Meng-Yu Lu, Jun Li*, Heng-Xin Jian, Xin Zhao, Ming-Jian Yuan, Tong-Bu Lu*eScience, 2025, DOI:10.1016/j.esci.2025.100500. LINK |
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22. |
A versatile self-templating approach for constructing ternary halide perovskite heterojunctions to achieve concurrent enhancement in photocatalytic CO2 reduction activity and stabilityMeng-Ran Zhang, You-Xiang Feng,* Zhao-Lei Liu, Ke Su, Su-Xian Yuan, Min Zhang,* and Tong-Bu Lu*Adv. Funct. Mater., 2025, 2423656. LINK |
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21. |
Constructing strong built-in electric field in lead-free halide-perovskite-based heterojunction to boost charge separation for efficient CO2 photoreductionZhao-Lei Liu, Yan-Fei Mu, Xi-Rui Li, You-Xiang Feng, Min Zhang*, Tong-Bu Lu*Appl. Catal. B: Environ. Energy, 2025, 366, 125012. LINK |
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20. |
Photocatalytic CO2 reduction to methanol with metal free thiadiazole-based covalent organic frameworksYu-Chen Wang, Wen-Jie Shi*, Wei-Xue Tao, Yun Su, Xiang-Yang Wang, Cheng Wang, Di-Chang Zhong*, Tong-Bu Lu*Appl. Catal. B: Environ. Energy, 2025, 374, 125404. LINK |
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19. |
Recent advances in MOF-based dual-atom catalysts for CO2 reductionWen-Jie Shi and Tong-Bu Lu*Chem. Eur. J., 2025, 31, e202500636. LINK |
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18. |
Rapid electron transfer via imine- LINKed interface in dinuclear cobalt MOF@COF Z-scheme heterojunction for enhanced photocatalytic CO2 reduction with H2OYu-Chen Wang, Wen-Jie Shi*, Ji-Hong Zhang, Wei-Xue Tao, Di- Chang Zhong*, Tong-Bu LuChem. Eng. J., 2025, 517, 164327. LINK |
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17. |
Product control in visible-light-driven CO2 reduction by switching metal centers of binuclear catalystsChao Su, Hai-Hua Huang, Zubing Huang, Zilu Chen,* Anna Mo, Jia-Wei Wang, Huancheng Hu, Huahong Zou, Zhuofeng Ke, Fupei Liang,* Tong-Bu Lu,* and Dongcheng Liu*ACS. Catal., 2025, 15, 2522−2530. LINK |
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16. |
Direct partial transformation of 2D antimony oxybromide to halide perovskite heterostructure for efficient CO2 photoreductionSu-Xian Yuan, Ke Su, Meng-Ran Zhang, You-Xiang Feng, Yu Li,* Min Zhang,* and Tong-Bu LuSmall, 2025, 21, 2409909. LINK |
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15. |
Direct electroreduction of low-concentration CO2: progress and perspectiveJing-Jing Li,∇ Xue-Rong Qin,∇ Xiao-Ran Wang, Lin-Lin Wang, Zi-You Yu,* and Tong-Bu Lu*ACS Nano, 2025, 19, 10620−10629. LINK |
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14. |
Fluorinated covalent organic frameworks enable photocatalytic H2O2 production via a photoinduced framework radical pathwayWei xue Tao, Yu chen Wang, Ling hui Cong, Chen hui Zhang, Yan Gao, Hai feng Zheng, Wen jie Shi*, Di chang Zhong* & Tong bu Lu*Sci. China Chem., 2025, 68, DOI: 10.1007/s11426-025-2840-0. LINK |
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13. |
Intermarriage of InVO4 and BiVO4 via cation-exchange to boost charge separation for efficient photocatalytic CH4 oxidation to oxygenates Guang-Xing Dong†, Meng-Ran Zhang† , Cheng-Cheng Jiao, Zhao-Lei Liu, Ke Su, Min Zhang* & Tong-Bu Lu*Sci. China Chem., 2025, 68, 3807−3815. LINK |
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12. |
Recent progress in metal-organic frameworks (Part II-material application)Jiandong Pang†, Wentao Jiang†, Xue-Wen Zhang†, Hao-Long Zhou†, Yuxiu Sun†, Wei Gong†, Bin Wang†, Fuyin Ma†, Linwei He†, Long Chen†, Qiang Chen†, He-Qi Zheng†, Yuanjing Cui†, Wen-Jie Shi†, Chao Zhang†, Mei Wang†, Yue-Biao Zhang*, Jie-Peng Zhang*, Chongli Zhong*, Yong Cui*, Shuao Wang*, Jian-Rong Li*, Guodong Qian*, Tong-Bu Lu*, Huan Pang* & Xian-He Bu*Sci. China Chem., 2025, 68, 1642−1702. LINK
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11. |
High-selectivity electroreduction of low-concentration CO2 with large concentration fluctuationMengyu Qi†, Yanbin Ma†, Chao Zhang, Bingwei Li, Xueqing Yang, Zhaolin Shi, Simeng Liu, Changhua An, Jiqing Jiao* & Tongbu Lu*Sci. China Chem., 2025, 68, 1620−1626. LINK |
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10. |
Boosting photocatalytic CO2-to-CO conversion using a biomimetic dinuclear Co(II) complex through an HCO3−-mediated pathwayYuchen Wang, Wenjie Shi*, Weixue Tao, Jihong Zhang, Di-Chang Zhong* & Tongbu Lu*Sci. China Chem., 2025, 68, 974−949. LINK |
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9. |
Metal-organic frameworks with dinuclear metal centers for synergistically boosting CO2 photoreductionHui-Feng Wang, Wen-Jie Shi , Yu-Xin Yang , Bao-Xia Dong*, Tong-Bu Lu & Di-Chang Zhong*Sci. China Chem., 2025, 68, 201−208. LINK |
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8. |
Cu2O/lanthanide hydroxide boosting electrocatalytic CO2 reduction via stabilizing Cu(I)Ran Li†, Hang Yin†, Wen-Kai Jing, Jia-Lin Cheng, Xue-Rong Qin, Tong-Bu Lu, Hong-Juan Wang* & Zi-You Yu*Sci. China Chem., 2025, 68, 6533−6540. LINK |
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7. |
Pyrrolic nitrogen coordinated Ni2+ dual-atom catalyst for boosting CO2 electroreductionZhi-Wei Chen, Hong-Juan Wang, Chang Liu, Xiu-Li Lu, and Tong-Bu Lu*Sci. China Chem., 2025, 68, 570−579. LINK |
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6. |
Dual-metal synergistic catalysis for promoting electrocatalytic CO2 reductionPeng-Yu Shi, Yan Yan, Si-Yuan Yang, Jing-Jing Hao, Mei Wang* and Tong-Bu Lu*Chem. Sci., 2025, 16, 11711. LINK |
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5. |
A salen-based dinuclear cobalt(II) polymer with direct and indirect synergy for electrocatalytic hydrogen evolutionXiao-Mei Hu,+ Wen-Jie Shi,+* Jian-Hua Mei, Yu-Chen Wang, Wei-Xue Tao, Di-Chang Zhong* and Tong-Bu Lu*Chem. Sci., 2025, DOI: 10.1039/d5sc02073e. LINK |
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4. |
Small-size Au nanoparticles anchored on pyrenyl-graphdiyne for N2 electroreductionChang Liu, Chao Zhang, Tong-Bu Lu*Chin. J. Inorg. Chem., 2025, 41, 174−182. LINK |
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3. |
Polymer-assisted in-situ growth of Cs3Sb2Br9 on Co3O4 to boost sacrificial-agent-free photocatalytic CO2 reductionKe Su, Su-Xian Yuan, You-Xiang Feng, Guang-Xing Dong, Yan-Fei Mu, Min Zhang* , Tong-Bu Lu*Rare Metals, 2025, 44, 3194−3205. LINK |
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2. |
Constructing S-scheme heterojunction Cs3Bi2Br9/BiOBr via in-situ partial conversion to boost photocatalytic N2 fixationAn-Di Ren, Zhao-Lei Liu, Su-Xian Yuan , Min Zhang*, Tong-Bu LuJ. Colloid Int. Sci., 2025, 678, 1203−1212. LINK |
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1. |
Enhanced Anodic 5-Hydroxymethylfurfural Oxidationtoward Efficient Overall CO2 ElectrolysisFangyun Su, Zixian Ye, Zhenhai Zhao, Hongyu Jiao, Kefeng Wu, Jiawang Di, Yu Li*, and Tongbu Lu*Eur. J. Inorg. Chem., 2025, 28, e202500133. LINK |
