open access publication

Article, 2024

Size‐Dependent Multi‐Electron Donation in Metal‐Complex Quantum Dots Hybrid Catalyst for Photocatalytic Carbon Dioxide Reduction

Advanced Functional Materials, ISSN 1616-301X, 1616-3028, 10.1002/adfm.202315734

Contributors

Zhao, Qian [1] Abdellah, Mohamed A 0000-0002-6875-5886 [2] [3] [4] Cao, Yuehan 0000-0003-4073-6162 [5] Meng, Jie 0000-0002-3813-5221 [1] [4] Zou, Xian-Shao 0000-0002-9459-3147 [1] [4] Ene‐mark‐Rasmussen, Kasper [1] Lin, Weihua 0000-0003-3623-0353 [4] Li, Yi [5] Chen, Yijiang [5] Duan, Hengli [4] [6] Pan, Qinying 0000-0002-8773-989X [4] Zhou, Ying 0000-0001-9995-0652 [5] Pullerits, Tõnu 0000-0003-1428-5564 [4] Xu, Hong [7] Canton, Sophie E 0000-0003-4337-8129 [1] Niu, Yuran Niu [4] [6] Zheng, Kaibo 0000-0002-7236-1070 [1] [4]

Affiliations

  1. [1] Technical University of Denmark
    2. [NORA names: DTU Technical University of Denmark; University; Denmark; Europe, EU; Nordic; OECD];
  2. [2] South Valley University
    3. [NORA names: Egypt; Africa];
  3. [3] United Arab Emirates University
    4. [NORA names: United Arab Emirates; Asia, Middle East];
  4. [4] Lund University
    5. [NORA names: Sweden; Europe, EU; Nordic; OECD];
  5. [5] Southwest Petroleum University
    6. [NORA names: China; Asia, East];

Abstract

Abstract The effective conversion of carbon dioxide (CO 2 ) into valuable chemical fuels relies significantly on the donation of multiple electrons. Its efficiency  is closely linked to both the density and lifetime of excited charge carriers. In this study, a hybrid catalyst system comprising covalently bonded InP/ZnS quantum dots (QDs) and Re‐complexes is showcased. The electronic band alignment between the QDs and the Re‐complexes is revealed to dominate the multi‐electron transfer process for photocatalytic conversion to methane (CH 4 ). Notably, the size of the QDs is found to be a determining parameter. Among the three QD sizes investigated,  transient absorption spectroscopy studies unveil that rapid multi‐electron transfer from the QDs to the Re‐catalyst occurs in smaller QDs (2.3 nm) due to the substantial driving force. Consequently, the photocatalytic conversion of CO 2 to CH 4 is significantly enhanced with a turnover number of 6, corresponding to the overall apparent quantum yield of ≈1%. This research underscores the possibilities of engineering multi‐electron transfer by manipulating the electronic band alignment within a catalytic system. This can serve as a guide for optimizing photocatalytic CO 2 reduction.

Keywords

CH 4, CO 2, CO 2 reduction, CO 2 to CH 4, InP/ZnS quantum dots, QD size, Re catalysts, Re complexes, alignment, apparent quantum yield, band alignment, carbon dioxide, carbon dioxide reduction, carriers, catalyst, catalyst system, catalytic system, charge carriers, chemical, chemical fuels, conversion, conversion of carbon dioxide, covalently, density, dioxide, donation, dots, effective conversion, efficiency, electron, electronic band alignment, excited charge carriers, fuel, hybrid, hybrid catalyst, hybrid catalyst system, lifetime, metal complexes, methane, multi-electron transfer, multi-electron transfer processes, multiple electrons, number, parameters, photocatalytic CO 2 reduction, photocatalytic carbon dioxide reduction, photocatalytic conversion, photocatalytically, possibilities, process, quantum dots, quantum yield, reduction, research, size, study, system, transfer, transfer process, turnover, turnover number, yield

Funders

  • National Natural Science Foundation of China
  • Swedish Research Council
  • Carl Tryggers stiftelse för vetenskaplig forskning
  • The Velux Foundations

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