Fabricated Cu-doping and Sulfur Vacancies of CdIn2S4 Nanoflowers with co-Engineering Active Sites for Selective Photoreduction of CO2 to CH4

doi:10.1007/s40242-025-5097-6

Abstract

Abstract: Photocatalytic CO₂ reduction reaction (CO₂ RR) is usually limited by the weak adsorption capacity of the catalyst for CO₂ as well as the low product selectivity. In this paper, the electronic properties and catalytic reactive sites of CdIn₂S₄ surface atoms are modulated by Cu doping. Experimental and theoretical calculations show that the coordination environment around the Cd atoms changes due to the charge balance effect after Cu doping, which induces the formation of sulfur vacancies. The sulfur vacancies not only enhanced the adsorption capacity of CO₂, but also acted as charge-enriched centres to provide electrons to the Cu reactive sites and stabilized the reaction intermediates, which led to the highly selective generation of CH₄. Cu-doped CdIn₂S₄ catalysts exhibited excellent performance in photocatalytic reduction of CO₂, and the CH₄ yield of 47.01 μmol∙g^-1∙h^-1 with a selectivity of 97.8%. In this study, the synergistic interaction between sulfur vacancies and metal reactive sites enhances the adsorption and activation of CO₂ and effectively regulates the charge transfer process, providing a new strategy for optimising the performance of semiconductor photocatalysts.

Key words: Cu-doped, Sulfur vacancy, CO₂ reduction, Excellent selectivity of CH₄

CHANG Bingqing, XU Mengyang, LI Jinze, LIU Xiang, ZHANG Jisheng, ZHOU Weiqiang, ZHANG Yining, YAN Chenlong, WANG Huiqin, HUO Pengwei. Fabricated Cu-doping and Sulfur Vacancies of CdIn₂S₄ Nanoflowers with co-Engineering Active Sites for Selective Photoreduction of CO₂ to CH₄[J]. Chemical Research in Chinese Universities, 2025, 41(4): 850-858.

References

[1] Zhang W., Ma D., Pérez-Ramírez J., Chen Z., Advanced Energy and Sustainability Research, 2022, 3, 2100169.
[2] Song X., Liu X., Ren Z., Liu X., Wang M., Wu Y., Zhou W., Zhu Z., Huo P., Acta Physico-Chimica Sinica, 2025, 28, 100055.
[3] Jiang J., Wang X., Xu Q., Mei Z., Duan L., Guo H., Applied Catalysis B:Environmental, 2022, 316, 121679.
[4] Yan S., Zhang L., Shi S., Ren Y., Liu W., Li Y., Duan F., Lu S., Du M., Chen M., Chemical Research in Chinese Universities, 2025, 41, 121.
[5] Lei J., Zhou N., Sang S., Meng S., Low J., Li Y., Chinese Journal of Catalysis, 2024, 65, 163.
[6] Sadanandan A. M., Yang J. H., Devtade V., Singh G., Dharmarajan N. P., Fawaz M., Lee J. M., Tavakkoli E., Jeon C. H., Kumar P., Vinu A., Progress in Materials Science, 2024, 142, 101242.
[7] Huo Y., Zhang P., Chi J., Fang F., Song Y., Sun D., Advanced Energy Materials, 2024, 14, 2304282.
[8] Liu X., Wu Y., Li Y., Yang X., Ma Q., Luo J., Chemical Engineering Journal, 2024, 485, 149855.
[9] Meng W., Zhou Y., Zhou Y., Chinese Chemical Letters, 2025, 36, 109961.
[10] Kumar A., Khosla A., Sharma S. K., Dhiman P., Sharma G., Gnanasekaran L., Naushad M., Stadler F. J., Fuel, 2023, 333, 126267.
[11] Cai J., Li X., Su B., Guo B., Lin X., Lu X. F., Wang S., Journal of Materials Science & Technology, 2025, 234, 82.
[12] Xu H., Song X., Zhang Q., Yu C., Qiu J., Acta Physico-Chimica Sinica, 2024, 40, 2303040.
[13] Wen D., Wang N., Peng J., Majima T., Jiang J., Journal of Materials Science & Technology, 2025, 226, 93.
[14] Wang X., Zhao Z., Zahra K., Li J., Zhang Z., Chemical Research in Chinese Universities, 2023, 39, 580.
[15] Chang X., Wang T., Gong J., Energy Environ. Sci., 2016, 9, 2177.
[16] Ou H., Chong B., Bao J., Kou S., Li H., Li Y., Yan X., Lin B., Yang G., Advanced Materials, 2024, 36, 2404851.
[17] Feng C., Hu M., Zuo S., Luo J., Castaño P., Ren Y., Zhang H. R., Advanced Materials, 2025, 37, 2411813.
[18] Sun Y., Lai K., Li N., Gao Y., Ge L., Applied Catalysis B:Environment and Energy, 2024, 357, 124302.
[19] Wang J., Yang C., Mao L., Cai X., Geng Z., Zhang H., Zhang J., Tan X., Ye J., Yu T., Advanced Functional Materials, 2023, 33, 2213901.
[20] Huang H., Lin Q., Niu Q., Ning J., Li L., Bi J., Yu Y., Chinese Journal of Catalysis, 2024, 60, 201.
[21] Hu M., Alharbi J., Zhang H., Al Qahtani H. S., Feng C., Chemical Research in Chinese Universities, 2025, 41, 1.
[22] Bi J., Cheng Y., Sun M., Guo X., Wang S., Zhao Y., Chinese Chemical Letters., 2024, 35, 109639.
[23] Xiao Q., Liu T., Zhou Q., Li L., Chang C., Gao D., Li D., You F., Chemical Research in Chinese Universities, 2024, 40, 484.
[24] Zhang Y., Li J., Zhou W., Liu X., Song X., Chen S., Wang H., Huo P., Applied Catalysis B:Environmental, 2024, 342, 123449.
[25] Zhong R., Liang Y., Huang F., Liang S., Liu S., Chinese Journal of Catalysis, 2023, 53, 109.
[26] Kale B. B., Baeg J. O., Lee S. M., Chang H., Moon S. J., Lee C. W., Advanced Functional Materials, 2006, 16, 1349.
[27] He J., Li B., Yu J., Qiao L., Li S., Zu X., Optical Materials, 2020, 108, 110231.
[28] Ding S., Liu X., Shi Y., Liu Y., Zhou T., Guo Z., Hu J., ACS Applied Materials & Interfaces, 2018, 10, 17911.
[29] Li Y., Gao C., Long R., Materials Today Chemistry, 2019, 11, 197.
[30] Li P., Cui Y., Wang Z., Dawson G., Shao C., Dai K., Acta Physico-Chimica Sinica, 2025, 41, 100065.
[31] Vu MH., Nguyen C. C., Sakar M., Do T. O., Physical Chemistry Chemical Physics, 2017, 19, 29429.
[32] Yao Y., Qin J., Chen H., Wei F., Liu X., Wang J., Wang S., Journal of Hazardous Materials, 2015, 291, 28.
[33] Dong Z., Zhang L., Gong J., Zhao Q., Chemical Engineering Journal, 2021, 403, 126383.
[34] Huang L., Li B., Su B., Zhang C., Hou Y., Ding Z., Wang S., Journal of Materials Chemistry A, 2020, 8, 7177.
[35] Zhang X., Chen Z., Luo Y., Han X., Jiang Q., Zhou T., Yang H., Hu J., Journal of Hazardous Materials, 2021, 405, 124128.
[36] Li S., Hu S., Zhang J., Jiang W., Liu J., Journal of Colloid and Interface Science, 2017, 497, 93.
[37] Li S., Shen X., Liu J., Zhang L., Environmental Science:Nano, 2017, 4, 1155.
[38] Ji H., Liu Y., Du G., Huang T., Zhu Y., Sun Y., Pang H., Chemical Research in Chinese Universities, 2024, 40, 943.
[39] Wang F., Zhang S., Qiu H., Liu Y., Guo L., Journal of Materials Science & Technology, 2024, 189, 146.
[40] Dong H., Zuo Y., Song N., Hong S., Xiao M., Zhu D., Sun J., Chen G., Li C., Applied Catalysis B:Environmental, 2021, 287, 119954.
[41] Li Z., Huang Y., Huang Y., Waterhouse G. I., Wang Z., Mao Y., Liang Z., Luo X., Chemical Engineering Journal, 2024, 495, 153310.
[42] Wang F., Zhang W., Liu H., Cao R., Chen M., Chemosphere, 2023, 338, 139574.
[43] Lai K., Sun Y., Li N., Gao Y., Li H., Ge L., Ma T., Advanced Functional Materials, 2024, 34, 2409031.
[44] Mao L., Li Q., Zhou Q., Dang W., Zhao Y., Sun Y., Journal of Colloid and Interface Science, 2025, 685, 1122.
[45] Yang J., Hou Y., Sun J., Liang T., Zhu T., Liang J., Lu X., Yu Z., Zhu H., Wang S., Chemical Engineering Journal, 2023, 452, 139522.
[46] Yin S., Zhao X., Jiang E., Yan Y., Zhou P., Huo P., Energy & Environmental Science, 2022, 15, 1556.
[47] Xing F., Li Q. Y., Li J. Y., Journal of Colloid and Interface Science, 2025, 691, 137388.
[48] Bolunduţ L., Păşcuţă P., Culea E., Boşca M., Pop L., Ştefan R., Journal of Materials Science, 2020, 55, 9962.
[49] Zhang W., Song C. C., Wang J. W., Cai S. T., Gao M. Y., Feng Y. X., Lu T. B., Chinese Journal of Catalysis, 2023, 52, 1766.
[50] Wang S., Wang S., Tang R., Liu Y., Chen H., Journal of Colloid and Interface Science, 2024, 676, 959.
[51] Du Z., Guo C., Guo M., Meng S., Yang Y., Yu Z., Zheng X., Zhang S., Chen C., Chen S., Journal of Colloid and Interface Science, 2025, 677, 571.
[52] Xiao M., Li D., Wei Y., He Y., Wang Z., Yu R., Chemical Research in Chinese Universities, 2024, 40, 513.
[53] Jian H., Deng K., Wang T., Huang C., Wu F., Huo H., Ouyang B., Liu X., Ma J., Kan E., Li A., Chinese Chemical Letters, 2024, 35, 108651.
[54] Wang X., Wang Z., Li Y., Wang J., Zhang G., Applied Catalysis B:Environmental, 2022, 319, 121895.
[55] Li J., Pei X., Wang Z., Li Y., Zhang G., Applied Surface Science, 2022, 605, 154632.
[56] Xu M., Chang B., Li J., Wang H., Huo P., Chinese Journal of Catalysis, 2025, 71, 114.

Fabricated Cu-doping and Sulfur Vacancies of CdIn₂S₄ Nanoflowers with co-Engineering Active Sites for Selective Photoreduction of CO₂ to CH₄

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 12

Recommended Articles

Metrics

Comments

[1]	TANG Liguang, XU Huan, XU Yangrui, CHENG Yu, CHU Yansong, FENG Sheng, LIU Haixia, LIU Xinlin, SONG Minshan, LU Ziyang. Cu Sites Synergistic Double Heterojunction Engineering for Enhancing CO₂ Photoreduction [J]. Chemical Research in Chinese Universities, 2025, 41(4): 812-821.
[2]	LI Dan. Frontiers in Catalytic Technologies for Carbon Neutrality: Advances and Prospects [J]. Chemical Research in Chinese Universities, 2025, 41(3): 472-483.
[3]	SUI Xiqing, WU Limin, JIA Shunhan, JIN Xiangyuan, SUN Xiaofu, HAN Buxing. CO₂/NO_x-involved Electrochemical C-N Coupling Reactions [J]. Chemical Research in Chinese Universities, 2024, 40(5): 764-775.
[4]	XIAO Qi, LIU Ting, ZHOU Qianhe, LI Liangyu, CHANG Chuntao, GAO Dawei, LI Danyang, YOU Feifei. Nanostructured ZnO/ZnS with Type-II Hetero-junction for Efficient CO₂ Photoreduction [J]. Chemical Research in Chinese Universities, 2024, 40(3): 484-489.
[5]	MAO Yuanxin, CHEN Shi, JIA Zihan, DONG Xufeng, and MAO Qing. CV-etched Nanostructured Ag Foils for Efficient Electrochemical CO₂ Reduction [J]. Chemical Research in Chinese Universities, 2023, 39(6): 1031-1036.
[6]	LI Boyang, OU Honghui, CHEN Shenghua, SU Ya-Qiong, WANG Dingsheng. Recent Advances in CO₂ Reduction Reaction to Value-added C1 Products by Single-atom Catalysts [J]. Chemical Research in Chinese Universities, 2023, 39(4): 527-544.
[7]	WANG Xinyi, ZHAO Zhenwei, ZAHRA Kiran, LI Junjun, ZHANG Zhicheng. Sub-nanomaterials for Photo/Electro-catalytic CO₂ Reduction: Achievements, Challenges, and Opportunities [J]. Chemical Research in Chinese Universities, 2023, 39(4): 580-598.
[8]	DU Yuncheng, ZHENG Xuchen, XUE Yurui, LI Yuliang. Bismuth/Graphdiyne Heterostructure for Electrocatalytic Conversion of CO₂ to Formate [J]. Chemical Research in Chinese Universities, 2022, 38(6): 1380-1386.
[9]	HE Kai, LIU Shijia, ZHAO Guiyan, QIN Yucai, BI Yanfeng, SONG Lijuan. Ni-W Catalysts Supported on Mesoporous SBA-15: Trace W Steering CO₂ Methanation [J]. Chemical Research in Chinese Universities, 2022, 38(6): 1504-1511.
[10]	XU Guangyuan, LIU Qin, YAN Huan. Recent Advances of Single-atom Catalysts for Electro-catalysis [J]. Chemical Research in Chinese Universities, 2022, 38(5): 1146-1150.
[11]	MIAO Tianchang, DI Xin, HAO Feini, ZHENG Gengfeng, HAN Qing. Polymeric Carbon Nitride-based Single Atom Photocatalysts for CO₂ Reduction to C₁ Products [J]. Chemical Research in Chinese Universities, 2022, 38(5): 1197-1206.
[12]	JI Yuancheng, XU Jiayun, SUN Hongcheng, and LIU Junqiu. Artificial Photosynthesis(AP): from Molecular Catalysts to Heterogeneous Materials [J]. Chemical Research in Chinese Universities, 2022, 38(3): 688-697.