Overall Utilization of Photoexcited Charges for Simultaneous Photocatalytic Redox Reactions

Citation: Zhongliao Wang, Jing Wang, Jinfeng Zhang, Kai Dai. Overall Utilization of Photoexcited Charges for Simultaneous Photocatalytic Redox Reactions[J]. Acta Physico-Chimica Sinica, 2023, 39(6): 220903. doi: 10.3866/PKU.WHXB202209037 shu

光激发电荷在光催化氧化还原反应中的全利用

王中辽 ^†, ,
汪静 ^†, ,
张金锋 ^, ,
代凯 ^,

.
淮北师范大学, 绿色和精准合成化学及应用教育部重点实验室和污染物敏感材料与环境修复安徽省重点实验室, 物理与电子信息学院, 安徽淮北 235000

通讯作者: 张金锋, jfzhang@chnu.edu.cn
代凯, daikai940@chnu.edu.cn

基金项目:
国家自然科学基金 22278169

国家自然科学基金 51973078

安徽省杰出青年基金 1808085J14

安徽省教育厅重大项目 KJ2020ZD005

摘要: 光催化转化CO₂为碳氢燃料，分解水产氢，选择性有机合成，还原N₂为NH₃，降解毒害的有机污染物等对解决能源环境问题有重要意义。早在1972年，研究者利用TiO₂通过光催化实现了全面分解水产氢和产氧。由于低的可见光利用率，严重的载流子复合和过高的水氧化能垒导致光催化全面水分解的效率极低。由于氢相对于氧更具有经济价值，因此牺牲剂辅助的光催化产氢被大量研究。由于牺牲剂可以快速的消耗光生空穴，有效降低了氧化端的能垒，光催化产氢的效率相比于光催化水分解的效率提高了3–4个量级。然而，牺牲剂的使用不仅导致了光生空穴的浪费，成本的提高，还导致了潜在的环境问题。近些年，研究者通过将光催化还原反应和光催化氧化反应结合在一起实现了电子空穴的全面利用，并改进了氧化和还原的效率。同时，电子空穴的全面利用也有效的促进了电荷的分离并提高了催化剂的稳定性。然而，由于全面氧化还原的设计难度大，反应过程复杂，因此光催化全面氧化还原的机理尚不够明确，仍然需要大量的探索。在这篇综述中，首先从光捕获、光激发电荷分离、氧化还原反应的热力学和动力学过程等角度讨论了光催化的基本原理。然后根据不同的光催化氧化反应和光催化还原反应的耦合，比如光催化整体水分解、光催化产H₂与有机氧化耦合、光催化CO₂还原与有机氧化耦合、光催化产H₂O₂与有机氧化耦合、光催化N₂还原与N₂氧化耦合、光催化有机还原与有机氧化耦合等光催化全面氧化还原反应进行了系统分类。随后，从光催化材料的设计、反应条件、反应物和产物的多样性等方面详细考虑了光催化氧化还原反应的设计要点。此外，通过功函数、电子密度差、Bader电荷、吸附自由能的变化，讨论了密度泛函理论(DFT)计算在揭示光激发电荷转移、中间体转变过程中的速率决定步骤和氧化还原反应势垒方面的重要作用。然后，结合典型案例，尽可能通过原位表征和DFT计算，详细分析了各种光催化氧化还原反应的活性和机理。最后，从构建S型异质结光催化剂、合理负载助催化剂、设计光催化剂形貌、开发新型光催化剂、合理选择氧化半反应和还原半反应耦合、原位表征和DFT计算的结合等角度对光催化全面氧化还原反应的应用进行了总结和展望。该工作为光催化整体氧化还原反应的设计策略和机理洞察提供了参考。

关键词:

English

Overall Utilization of Photoexcited Charges for Simultaneous Photocatalytic Redox Reactions

Key Laboratory of Green and Precise Synthetic Chemistry and Applications, Ministry of Education; Anhui Province Key Laboratory of Pollutant Sensitive Materials and Environmental Remediation, School of Physics and Electronic Information, Huaibei Normal University, Huaibei 235000, Anhui Province, China
^†These authors contributed equally to this work.

Corresponding author: Jinfeng Zhang, jfzhang@chnu.edu.cn Kai Dai, daikai940@chnu.edu.cn

Received Date: 26 September 2022
Accepted Date: 26 October 2022
Revised Date: 20 October 2022
Available Online: 15 June 2023
Fund Project:

Abstract: The photoconversion of CO₂ to carbon-containing fuels, splitting water into H₂, selective organic synthesis, reduction of N₂ to NH₃, and hazardous organic contaminant degradation represent feasible schemes for solving environmental and energy issues. In 1972, TiO₂ was applied for decomposing water into H₂ and O₂ via photocatalysis. Owing to its the low visible-light utilization, fast charge recombination, and high energy barrier for water oxidation, overall photocatalytic water-splitting efficiency is extremely low. Because H₂ is more economically valuable than O₂, sacrificial agent-assisted photocatalytic H₂ evolution has been extensively investigated. Because the sacrificial agent can quickly consume photoexcited holes and effectively reduce the water oxidation energy barrier, photocatalytic H₂ evolution efficiency can be increased by 3–4 orders of magnitude compared to photocatalytic water splitting. However, the overuse of sacrificial agents contributes to wasted photoexcited holes and expensive processes, while presenting potential environmental issues. Recently, overall charge utilization and improved redox efficiency have been achieved by coupling photocatalytic reduction with oxidation reactions. Moreover, overall charge utilization can boost charge separation and increase photocatalyst durability. However, the photocatalytic mechanism of the overall redox reactions remains unclear, owing to the complex reaction processes and design difficulties. Herein, the basic principles of photocatalysis are discussed from the perspective of light harvesting, photoexcited charge separation, thermodynamics, and redox reaction kinetics. Photocatalytic redox reactions, including overall water photodecomposition, photocatalytic H₂ evolution coupled with organic oxidation, photocatalytic CO₂ reduction coupled with organic oxidation, photocatalytic H₂O₂ production coupled with organic oxidation, photocatalytic N₂ reduction coupled with N₂ oxidation, and photocatalytic organic reduction coupled with organic oxidation, can be systematically classified according to the coupling of photocatalytic oxidation reactions with photocatalytic reduction reactions. Subsequently, the design of photocatalytic redox reactions is considered in terms of the modulation of photocatalyst materials, reaction conditions, and diversity of reactants and products. In addition, the vital role of density functional theory (DFT) calculations for unveiling photoexcited charge transfer, rate-determining steps, and redox reaction barriers are discussed in the context of the work function, electron density difference, Bader charge, and variation in the intermediate adsorption free energy profiles. The activity and mechanism of various photocatalytic redox reactions were elaborately analyzed through in situ characterizations and DFT calculations using representative cases. Finally, the overall photocatalytic redox reactions were summarized with a focus on the construction of an S-scheme heterojunction photocatalyst, reasonable loading of co-catalysts, photocatalyst morphology regulation, novel photocatalyst development, reasonable selection of the oxidation half-reaction and reduction half-reaction for coupling, and combined in situ characterization and DFT calculations. This work provides a reference for promising design strategies and insight into the mechanism of overall photocatalytic redox reactions.

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沈阳化工大学材料科学与工程学院沈阳 110142

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通讯作者: 张金锋, jfzhang@chnu.edu.cn
代凯, daikai940@chnu.edu.cn

English

Overall Utilization of Photoexcited Charges for Simultaneous Photocatalytic Redox Reactions

Corresponding author: Jinfeng Zhang, jfzhang@chnu.edu.cn Kai Dai, daikai940@chnu.edu.cn

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中国化学会秘书处

光激发电荷在光催化氧化还原反应中的全利用

通讯作者: 张金锋, jfzhang@chnu.edu.cn 代凯, daikai940@chnu.edu.cn

English

Overall Utilization of Photoexcited Charges for Simultaneous Photocatalytic Redox Reactions

Corresponding author: Jinfeng Zhang, jfzhang@chnu.edu.cn Kai Dai, daikai940@chnu.edu.cn

CCS Chemistry：嵌段共聚物自组装成 “三明治”二维有机材料，实现纳米级压力传感功能

CCS Chemistry：颜徐州、鲍哲南： 你的皮肤可能是一片SPMs

CCS Chemistry：工作高效不疲劳，只须让催化剂动起来

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通讯作者: 陈斌, bchen63@163.com

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代凯, daikai940@chnu.edu.cn

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