褐色聚合氮化碳纳米线双极光催化体系实现生物多元醇氧化与CO2还原协同产CO

doi:10.1016/S1872-2067(25)64928-X

催化学报 ›› 2026, Vol. 84: 214-225.DOI: 10.1016/S1872-2067(25)64928-X

褐色聚合氮化碳纳米线双极光催化体系实现生物多元醇氧化与CO₂还原协同产CO

陈杨林^a, 方瑞明^a^,^e, 赵慧博^c, 封敏君^d, 侯卫东^b, Tze Chien Sum^d, Wen Liu^c, 王亮^b(), Lydia Helena Wong^a(), 薛灿^a()

^a 南洋理工大学材料科学与工程学院, 新加坡, 新加坡
^b 上海大学环境与化学工程学院, 纳米化学与生物学研究所, 上海 200444, 中国
^c 南洋理工大学化学与生物化学学院, 新加坡, 新加坡
^d 南洋理工大学物理与应用物理学院, 新加坡, 新加坡
^e 安徽工业大学能源与环境学院, 安徽马鞍山 243002, 中国

收稿日期:2025-08-28 接受日期:2025-10-19 出版日期:2026-05-18 发布日期:2026-04-16
通讯作者: *电子信箱: wangl@shu.edu.cn (王亮),
lydiawong@ntu.edu.sg (Lydia Helena Wong),
cxue@ntu.edu.sg (薛灿).

Bipolar photocatalysis for CO generation via biopolyol oxidation and CO₂ reduction over brown polymeric carbon nitride nanowires

Yanglin Chen^a, Ruiming Fang^a^,^e, Huibo Zhao^c, Minjun Feng^d, Weidong Hou^b, Tze Chien Sum^d, Wen Liu^c, Liang Wang^b(), Lydia Helena Wong^a(), Can Xue^a()

^a School of Materials Science and Engineering, Nanyang Technological University, Singapore 639798, Singapore
^b Institute of Nanochemistry and Nanobiology, School of Environmental and Chemical Engineering, Shanghai University, Shanghai 200444, China
^c School of Chemistry, Chemical Engineering and Biotechnology, Nanyang Technological University, Singapore 637459, Singapore
^d Division of Physics and Applied Physics, School of Physical and Mathematical Sciences, Nanyang Technological University, Singapore 637371, Singapore
^e School of Energy and Environment, Anhui University of Technology, Maanshan 243002, Anhui, China

Received:2025-08-28 Accepted:2025-10-19 Online:2026-05-18 Published:2026-04-16
Contact: lydiawong@ntu.edu.sg (L. H. Wong),
cxue@ntu.edu.sg (C. Xue).

摘要/Abstract

摘要：

一氧化碳(CO)是重要的化工合成中间体和能源载体, 传统制备途径依赖煤炭或甲烷蒸汽重整, 不仅能耗高且伴随大量碳排放. 相比之下, 利用生物质替代化石资源生产CO, 不仅可实现碳中和, 也契合可再生能源驱动的绿色化工方向. 生物多元醇是生物质转化的重要平台分子, 其光催化脱羰反应能够在温和条件下生成CO. 然而, 现有体系普遍需强碱或紫外光激发, 难以在可见光条件下高效进行. 同时, 生物多元醇氧化常伴随副产H₂的生成, 降低CO纯度. 若能将该氧化过程与CO₂还原反应偶联, 不仅可消耗氢源, 提高CO产率, 还能实现碳资源的循环利用. 因此, 构建在可见光驱动下可同步实现生物多元醇脱羰与CO₂还原的“双极光催化CO生成体系”具有重要的科学意义与应用价值.

本文通过调控聚合氮化碳(CN)的能带结构与光吸收特性, 成功制备出具有宽光谱响应的褐色聚合氮化碳纳米线(CNW), 并构建了在无碱、无金属、室温条件下运行的双极光催化CO生成体系. CNW由三聚氰胺、三聚氯氰及氰尿酸经溶剂热-热解法合成. 氧元素的引入有效破坏了七嗪结构单元的对称性, 导致电子结构重新分布, 使CNW的光吸收边拓展至约740 nm. 与未掺杂的CN相比, CNW的带隙由2.76 eV缩窄至1.91 eV, 但其价带与导带位置依然适宜于同时驱动CO₂还原与醇类氧化反应. 稳态荧光光谱、瞬态荧光光谱、飞秒瞬态吸收谱以及电化学阻抗分析表明, CNW具有更高的电子-空穴分离效率与载流子迁移能力, 即使在长波(λ > 700 nm)光辐照下, 仍能产生明显的光电流. 在以甘油为模型底物、CO₂饱和的体系中, CNW在全光谱照射下可实现724 μmol g^‒1 CO生成速率和99%的CO纯度, 活性较未掺杂CN提高3.4倍; 在λ > 420 nm可见光辐照条件下, CNW的CO产率是CN的7.1倍. 且CNW在长波(λ > 700 nm)光辐照下仍保持活性. ¹³CO₂同位素标记实验确认CO产物来源于甘油氧化与CO₂还原的双路径. 该双极光催化CO生成体系对多种生物多元醇(乙醇、葡萄糖、果糖和半乳糖等)均展现出良好的底物适应性. 机理研究显示, 光生空穴氧化甘油经醛中间体发生脱羰反应生成CO, 光生电子将CO₂还原为CO. 原位红外与密度泛函理论计算进一步揭示, 相比于CN, 氧掺杂CNW增强了CO₂吸附与活化能力, 降低了CO₂* → COOH* → CO* → CO反应路径的能垒; 同时, 甘油分子在氧掺杂的CNW表面的吸附与活化更为容易. 由此构建的双极反应体系实现了光生电子用于CO₂还原, 光生空穴用于生物醇氧化的协同产CO机制, 在无碱、无金属条件下实现了高效的宽光谱太阳能转化.

综上, 本研究报道了基于氧掺杂聚合氮化碳纳米线的双极光催化体系, 为实现宽光谱辐照的生物质与CO₂协同转化提供了新思路. 该体系突破了传统金属催化剂限制, 为构建宽光谱响应的非金属光催化剂体系及实现碳中和化学转化提供了重要参考. 未来可通过界面耦合与异质结设计进一步提升光生载流子利用效率, 推动太阳能驱动碳循环化学的发展.

关键词: 双极CO生成体系, 生物多元醇氧化, 光催化CO₂还原, 褐色聚合氮化碳纳米线

Abstract:

Harnessing a single system capable of both oxidizing biopolyols and reducing carbon dioxide (CO₂) into carbon monoxide (CO) provides a sustainable pathway for simultaneous biomass conversion and CO₂ reduction. Traditional systems, however, are often limited by sluggish kinetics, requiring UV light or strongly alkaline media, which hampers their applicability under mild, visible-light conditions. In this study, we report an alkali- and metal-free photocatalytic CO production system operating at ambient temperature, employing brown polymeric carbon nitride nanowires (CNW) as the sole photocatalyst. The extended light-harvesting capacity of CNW enables efficient activity even under long-wavelength irradiation beyond 700 nm. The reaction pathways for biopolyol oxidative decarbonylation and CO₂-to-CO reduction were elucidated through a combination of in-situ spectroscopy and theoretical calculations. This visible-light-responsive dual-reaction platform directs photogenerated holes toward biopolyol oxidation and electrons toward CO₂ reduction, achieving efficient CO generation from renewable resources under mild conditions.

Key words: Bipolar CO production system, Biopolyols oxidation, Photocatalytic CO₂ reduction, Brown polymeric carbon nitride nanowire

陈杨林, 方瑞明, 赵慧博, 封敏君, 侯卫东, Tze Chien Sum, Wen Liu, 王亮, Lydia Helena Wong, 薛灿. 褐色聚合氮化碳纳米线双极光催化体系实现生物多元醇氧化与CO₂还原协同产CO[J]. 催化学报, 2026, 84: 214-225.

Yanglin Chen, Ruiming Fang, Huibo Zhao, Minjun Feng, Weidong Hou, Tze Chien Sum, Wen Liu, Liang Wang, Lydia Helena Wong, Can Xue. Bipolar photocatalysis for CO generation via biopolyol oxidation and CO₂ reduction over brown polymeric carbon nitride nanowires[J]. Chinese Journal of Catalysis, 2026, 84: 214-225.

×
扫码分享

导出引用管理器 EndNote|Ris|BibTeX

链接本文: https://www.cjcatal.com/CN/10.1016/S1872-2067(25)64928-X

https://www.cjcatal.com/CN/Y2026/V84/I5/214

图/表 7

Scheme 1. Producing CO from biomass pathways. (a) Traditional thermal gasification. Previous reported photocatalytic CO production system (b) and this bipolar photocatalytic CO production system (c).

Fig. 1. The conception of bipolar CO production system and basic characterization of photocatalysts. (a) Schematic illustration of photocatalytic bipolar CO production system via integrating oxidative decarbonylation of biopolyols with CO2 reduction. (b) SEM image of CNW. (c) TEM image of CNW. (d) EDS elemental mapping images of CNW. (e) High-resolution XPS spectra of C 1s of CN and CNW. (f) High-resolution XPS spectra of O 1s of CN and CNW. (g) solid-state 13C MAS NMR spectra of CN and CNW.

Fig. 2. Characterization of the photo-electro properties of photocatalysts. (a) UV-vis-NIR DRS spectra of CN and CNW, the insets show the digital pictures of CN and CNW. (b) Band structures of CN and CNW. (c) TR-PL decay plots of CN and CNW. (d) fs-TA spectra for CNW. (e) The corresponding decay kinetic at 550 nm for CNW. (f) Schematic representation of proposed exciton dissociation model in CNW. (g) Transient photocurrent response of CN and CNW under full spectrum irradiation. (h) Transient open-circuit potential decay curves of CN and CNW under full spectrum irradiation. (i) Transient photocurrent response under light with λ > 700 nm irradiation.

Fig. 3. Photocatalytic Performance. (a) Photocatalytic activity of CN and CNW under light irradiation using glycerol as a model biopolyol in a CO2-saturated environment. (b) The average generation rate of photocatalytic products under multiple experiments of control conditions by using CNW. (c) The mass spectra of CO peak driven from CNW under full spectrum irradiation using 13CO2 as CO2 source. (d) Comparing the photocatalytic performance of CNW with the presentative polymeric carbon nitride-based photocatalysts reported in the literature [10,42-50]. (e) The average generation rate of photocatalytic production driven from CNW with CO2. (f) The average generation rate of photocatalytic production driven from CNW with Ar.

Fig. 4. Photocatalytic CO2 reduction mechanism investigation. (a) Charge difference density distribution of CN and CNW with the adsorption of CO2 molecule. (The yellow and cyan isosurfaces represent electron accumulation and depletion with 0.002 e ??3, respectively). (b,c) In-situ DRIFTS spectra of CN under full spectrum irradiation for different durations at 298 K. (d,e) In-situ DRIFTS spectra of CNW under full spectrum irradiation for different durations at 298 K. (f) Gibbs free energy diagrams of photocatalytic CO2 reduction pathways on CN and CNW.

Fig. 5. Photocatalytic oxidative decarbonylation of biopolyols mechanism investigation. (a) HPLC data for the photocatalytic oxidative decarbonylation of glycerol over CNW under Ar atmosphere condition. (b) Photocatalytic activity of oxidative decarbonylation of glycerol, glyceraldehyde, propanol and propanal over CNW under Ar atmosphere condition. (c) GC data for liquid production of the photocatalytic oxidative decarbonylation of propanal with TEMPO under Ar atmosphere condition. (d) The mass spectrum of TEMPO-propanal adduct. (e) The proposed pathway for the photocatalytic oxidative decarbonylation of propanol and glycerol.

Scheme 2. Illustration of photocatalytic bipolar CO production system mechanism. Photocatalytic mechanism of the bipolar CO production system by integrating of photocatalytic CO2 reduction with oxidative decarbonylation reactions.

参考文献

[1]	F. Jiao, J. Li, X. Pan, J. Xiao, H. Li, H. Ma, M. Wei, Y. Pan, Z. Zhou, M. Li, S. Miao, J. Li, Y. Zhu, D. Xiao, T. He, J. Yang, F. Qi, Q. Fu, X. Bao, Science, 2016, 351, 1065-1068.
[2]	Y. Li, B. Liu, D. Yuan, H. Wang, Q. Wu, Y. Wang, J. Wang, X. San, Y. Luo, J. Ye, Nat. Catal., 2024, 7, 1350-1358.
[3]	M. L. Valderrama Rios, A. M. González, E. E. S. Lora, O. A. Almazán del Olmo, Biomass Bioenergy, 2018, 108, 345-370.
[4]	G. W. Huber, S. Iborra, A. Corma, Chem. Rev., 2006, 106, 4044-4098.
[5]	H. Zhou, M. Wang, F. Kong, Z. Chen, Z. Dou, F. Wang, J. Am. Chem. Soc., 2022, 144, 21224-21231.
[6]	X.-Y. Yu, J.-R. Chen, W.-J. Xiao, Chem. Rev., 2021, 121, 506-561.
[7]	Z. Liu, J. Ma, M. Hong, R. Sun, ACS Catal., 2023, 13, 2106-2117.
[8]	M. Wang, M. Liu, J. Lu, F. Wang, Nat. Commun., 2020, 11, 1083.
[9]	Z. Zhang, M. Wang, H. Zhou, F. Wang, J. Am. Chem. Soc., 2021, 143, 6533-6541.
[10]	Y. Wei, L. Chen, H. Chen, L. Cai, G. Tan, Y. Qiu, Q. Xiang, G. Chen, T.-C. Lau, M. Robert, Angew. Chem. Int. Ed., 2022, 61, e202116832.
[11]	G. Liao, Y. Gong, L. Zhang, H. Gao, G.-J. Yang, B. Fang, Energy Environ. Sci., 2019, 12, 2080-2147.
[12]	Y. Wang, H. Wang, S. Wang, Y. Fang, Angew. Chem. Int. Ed., 2024, 63, e202413768.
[13]	Z.-K. Xie, Y.-J. Jia, Y.-Y. Huang, D.-B. Xu, X.-J. Wu, M. Chen, W.-D. Shi, ACS Catal., 2023, 13, 13768-13776.
[14]	Y. Xu, M. Fan, W. Yang, Y. Xiao, L. Zeng, X. Wu, Q. Xu, C. Su, Q. He, Adv. Mater., 2021, 33, 2101455.
[15]	Q. Gu, Z. Gao, C. Xue, Small, 2016, 12, 3543-3549.
[16]	Y. Chen, M. Zheng, J. Sun, J. Xu, C. Wu, J. Liu, L. He, S. Xi, S. Li, C. Xue, ACS Catal., 2024, 14, 17321-17330.
[17]	H. Wang, S. Jiang, S. Chen, D. Li, X. Zhang, W. Shao, X. Sun, J. Xie, Z. Zhao, Q. Zhang, Y. Tian, Y. Xie, Adv. Mater., 2016, 28, 6940-6945.
[18]	Y. Li, X. Zhang, W. Hou, Z. Zhou, S. Zhang, H. Guo, J. Zhang, J. Xu, L. Wang, Appl. Catal. B, 2026, 380, 125758.
[19]	H. Ou, S. Ning, P. Zhu, S. Chen, A. Han, Q. Kang, Z. Hu, J. Ye, D. Wang, Y. Li, Angew. Chem. Int. Ed., 2022, 61, e202206579.
[20]	P. Qiu, C. Xu, H. Chen, F. Jiang, X. Wang, R. Lu, X. Zhang, Appl. Catal. B, 2017, 206, 319-327.
[21]	X. Li, I. V. Sergeyev, F. Aussenac, A. F. Masters, T. Maschmeyer, J. M. Hook, Angew. Chem. Int. Ed., 2018, 57, 6848-6852.
[22]	Z. Wei, M. Liu, Z. Zhang, W. Yao, H. Tan, Y. Zhu, Energy Environ. Sci., 2018, 11, 2581-2589.
[23]	Y. Chen, Y. Qu, P. Xu, X. Zhou, J. Sun, J. Colloid Interface Sci., 2021, 601, 326-337.
[24]	Y. Gao, Y. Zhu, L. Lyu, Q. Zeng, X. Xing, C. Hu, Environ. Sci. Technol., 2018, 52, 14371-14380.
[25]	H. Guo, L. Zhou, K. Huang, Y. Li, W. Hou, H. Liao, C. Lian, S. Yang, D. Wu, Z. Lei, Z. Liu, L. Wang, Adv. Funct. Mater., 2024, 34, 2402650.
[26]	Y. Wang, R. Godin, J. R. Durrant, J. Tang, Angew. Chem. Int. Ed., 2021, 60, 20811-20816.
[27]	D. Zhao, Y. Wang, C.-L. Dong, Y.-C. Huang, J. Chen, F. Xue, S. Shen, L. Guo, Nat. Energy, 2021, 6, 388-397.
[28]	H. Guo, Y. Lu, Z. Lei, H. Bao, M. Zhang, Z. Wang, C. Guan, B. Tang, Z. Liu, L. Wang, Nat. Commun., 2024, 15, 4843.
[29]	Y. Chen, X. Liu, L. Hou, X. Guo, R. Fu, J. Sun, Chem. Eng. J., 2020, 383, 123132.
[30]	B. Zhai, H. Li, G. Gao, Y. Wang, P. Niu, S. Wang, L. Li, Adv. Funct. Mater., 2022, 32, 2207375.
[31]	Y. Chen, L. He, H.-R. Tan, X. Lin, S. Jaenicke, G.-K., Chuah, J. Mater. Chem. A, 2023, 11, 12342-12353.
[32]	P. Xia, S. Cao, B. Zhu, M. Liu, M. Shi, J. Yu, Y. Zhang, Angew. Chem. Int. Ed., 2020, 59, 5218-5225.
[33]	G. Zhou, C. Bi, X. Qian, Y. Chen, H. Liu, X. Ning, C. Xue, P. Ding, X. Wang, X. Zhu, ACS Catal., 2025, 15, 15972-15981.
[34]	P. Liu, Z. Huang, X. Gao, X. Hong, J. Zhu, G. Wang, Y. Wu, J. Zeng, X. Zheng, Adv. Mater., 2022, 34, 2200057.
[35]	S. Wang, T. He, P. Chen, A. Du, K. K. Ostrikov, W. Huang, L. Wang, Adv. Mater., 2020, 32, 2001385.
[36]	Y. Guo, J. Li, Y. Yuan, L. Li, M. Zhang, C. Zhou, Z. Lin, Angew. Chem. Int. Ed., 2016, 55, 14693-14697.
[37]	Q. Ruan, T. Miao, H. Wang, J. Tang, J. Am. Chem. Soc., 2020, 142, 2795-2802.
[38]	W. Li, Z. Wei, K. Zhu, W. Wei, J. Yang, J. Jing, D. L. Phillips, Y. Zhu, Appl. Catal. B, 2022, 306, 121142.
[39]	M. Qian, X.-L. Wu, M. Lu, L. Huang, W. Li, H. Lin, J. Chen, S. Wang, X. Duan, Adv. Funct. Mater., 2023, 33, 2208688.
[40]	Z. Jiang, W. Wan, H. Li, S. Yuan, H. Zhao, P. K. Wong, Adv. Mater., 2018, 30, 1706108.
[41]	Y. Li, Y. Guo, D. Luan, X. Gu, X. W. D. Lou, Angew. Chem. Int. Ed., 2023, 62, e202310847.
[42]	S. Hu, P. Qiao, X. Yi, Y. Lei, H. Hu, J. Ye, D. Wang, Angew. Chem. Int. Ed., 2023, 62, e202304585.
[43]	P. Chen, B. Lei, X.-A. Dong, H. Wang, J. Sheng, W. Cui, J. Li, Y. Sun, Z. Wang, F. Dong, ACS Nano, 2020, 14, 15841-15852.
[44]	C. Cometto, R. Kuriki, L. Chen, K. Maeda, T.-C. Lau, O. Ishitani, M. Robert, J. Am. Chem. Soc., 2018, 140, 7437-7440.
[45]	W. Zhen, J. Sun, X. Ning, X. Shi, C. Xue, Appl. Catal. B, 2021, 298, 120568.
[46]	R. Kuriki, O. Ishitani, K. Maeda, ACS Appl. Mater. Interfaces, 2016, 8, 6011-6018.
[47]	S. Gong, X. Teng, Y. Niu, X. Liu, M. Xu, C. Xu, L. Ji, Z. Chen, Appl. Catal. B, 2021, 298, 120521.
[48]	J. Zhou, W. Chen, C. Sun, L. Han, C. Qin, M. Chen, X. Wang, E. Wang, Z. Su, ACS Appl. Mater. Interfaces, 2017, 9, 11689-11695.
[49]	Q. Liu, Z. Chen, W. Tao, H. Zhu, L. Zhong, F. Wang, R. Zou, Y. Lei, C. Liu, X. Peng, J. Mater. Chem. A, 2020, 8, 11761-11772.
[50]	H. Yu, E. Haviv, R. Neumann, Angew. Chem. Int. Ed., 2020, 59, 6219-6223.
[51]	Y. Chen, Y. Qu, X. Zhou, D. Li, P. Xu, J. Sun, ACS Appl. Mater. Interfaces, 2020, 12, 41527-41537.
[52]	X. Sun, L. Sun, G. Li, Y. Tuo, C. Ye, J. Yang, J. Low, X. Yu, J. H. Bitter, Y. Lei, D. Wang, Y. Li, Angew. Chem. Int. Ed., 2022, 61, e202207677.
[53]	J. Cheng, Y. Hou, K. Lian, H. Xiao, S. Lin, X. Wang, ACS Catal., 2022, 12, 1797-1808.
[54]	H.-B. Zhao, J.-N. Huang, Q. Qin, H.-Y. Chen, D.-B. Kuang, Small, 2023, 19, 2302022.
[55]	J. Zhou, B. Gao, D. Wu, C. Tian, H. Ran, W. Chen, Q. Huang, W. Zhang, F. Qi, N. Zhang, Y. Pu, J. Qiu, Z. Hu, J. Du, Z. Liu, Y. Leng, X. Tang, Adv. Funct. Mater., 2024, 34, 2308411.
[56]	Y. Ma, X. Yi, S. Wang, T. Li, B. Tan, C. Chen, T. Majima, E. R. Waclawik, H. Zhu, J. Wang, Nat. Commun., 2022, 13, 1400.
[57]	W. Shangguan, Q. Liu, Y. Wang, N. Sun, Y. Liu, R. Zhao, Y. Li, C. Wang, J. Zhao, Nat. Commun., 2022, 13, 3894.
[58]	X. Li, L. Li, G. Chen, X. Chu, X. Liu, C. Naisa, D. Pohl, M. Löffler, X. Feng, Nat. Commun., 2023, 14, 4034.
[59]	H. Zhou, M. Wang, F. Wang, Chem, 2022, 8, 465-479.
[60]	H. Lu, T.-Y. Yu, P.-F. Xu, H. Wei, Chem. Rev., 2021, 121, 365-411.
[61]	F. Kong, H. Zhou, Z. Chen, Z. Dou, M. Wang, Angew. Chem. Int. Ed., 2022, 61, e202210745.
[62]	H.-A. Ho, K. Manna, A. D. Sadow, Angew. Chem. Int. Ed., 2012, 51, 8607-8610.

褐色聚合氮化碳纳米线双极光催化体系实现生物多元醇氧化与CO₂还原协同产CO

Bipolar photocatalysis for CO generation via biopolyol oxidation and CO₂ reduction over brown polymeric carbon nitride nanowires

RichHTML

PDF

Supporting Information

可视化

摘要/Abstract

引用本文

使用本文

扫码分享

图/表 7

参考文献

相关文章 15

编辑推荐

Metrics

[1]	蒋浩朋, 李金河, 于晓慧, 董慧龙, 王伟康, 刘芹芹. β-酮烯胺共价键桥接的S型异质结实现同步光还原CO₂为CO以及茴香醇选择性氧化为茴香醛[J]. 催化学报, 2026, 80(1): 113-122.
[2]	张琳, 张慧, 方敬红, 崔嘉琳, 刘洁, 刘辉, 孙立水, 孙琼, 董立峰, 赵英杰. 高共轭和化学稳定的三维共价有机框架材料用于高效光催化CO₂还原[J]. 催化学报, 2025, 74(7): 144-154.
[3]	李存军, 何杰, 蔡天乐, 陈贤雷, 陶亨聪, 周英棠, 朱明山. 溴氧铋表面氧空位调控压电性质用于提升光催化CO₂还原反应效率与产物选择性[J]. 催化学报, 2025, 74(7): 130-143.
[4]	李亚慧, 陈宇, 郭锦瑜, 王锐, 赵淑娜, 李纲, 臧双全. 调控COF共价连接的多吡啶镍催化剂微环境促进光催化二氧化碳还原[J]. 催化学报, 2025, 74(7): 155-166.
[5]	李睿, 冯鹏飞, 李柏男, 朱佳玉, 张雅丽, 张泽, 张江威, 丁勇. 具有氧空位的多孔超薄NiO纳米片用于光催化CO₂还原[J]. 催化学报, 2025, 73(6): 242-251.
[6]	余维来. 共享金属节点的核壳型金属有机框架促进界面电荷转移[J]. 催化学报, 2025, 73(6): 8-11.
[7]	温东晓, 王楠, 彭嘉禾, 真嶋哲朗, 江吉周. Cu_xP/g-C₃N₄异质结催化剂Cu和P双位点协同光催化C-C偶联制备C₂H₄[J]. 催化学报, 2025, 69(2): 58-74.
[8]	甘广梅, 尹琳, 王小田, 邢巨元, 李源, 张高科. 界面工程调控的S型2D/1D Cs_0.32WO₃/WO₃·2H₂O异质结用于增强CO₂光还原: 协同电荷分离与活化机制研究[J]. 催化学报, 2025, 79(12): 219-230.
[9]	王小田, 胡波, 李源, 杨直雄, 张高科. Ni掺杂超薄Bi₄O₅Br₂调节偶极矩以增强内部电场促进光催化CO₂转化[J]. 催化学报, 2024, 66(11): 257-267.
[10]	宋明明, 宋相海, 刘鑫, 周伟强, 霍鹏伟. ZnIn₂S₄/MOF-808微球结构S型异质结光催化剂的制备及其光还原CO₂性能研究[J]. 催化学报, 2023, 51(8): 180-192.
[11]	邵秀丽, 李可, 李静萍, 程强, 王国宏, 王楷. 揭示NiS@Ta₂O₅纳米纤维中梯型电荷转移路径及光催化CO₂转化性能[J]. 催化学报, 2023, 51(8): 193-203.
[12]	李嘉明, 李源, 王小田, 杨直雄, 张高科. TiO₂上原子分散的Fe位点促进光催化CO₂还原: 增强的催化活性、 DFT计算和机制洞察[J]. 催化学报, 2023, 51(8): 145-156.
[13]	何厚伟, 王中辽, 代凯, 李素文, 张金锋. LSPR效应增强碳包覆In₂O₃/W₁₈O₄₉ S型异质结用于高效CO₂光还原[J]. 催化学报, 2023, 48(5): 267-278.
[14]	陈成成, 刘芳庭, 张巧钰, 张正国, 刘琼, 方晓明. 理论设计和实验研究吡啶掺杂聚合氮化碳提升光催化CO₂还原性能[J]. 催化学报, 2023, 46(3): 91-102.
[15]	王可, 程淼, 王楠, 张千一, 刘懿, 梁俊威, 管杰, 刘茂昌, 周建成, 李乃旭. 2D/2D超薄La₂Ti₂O₇/Ti₃C₂ Mxene肖特基异质结用于高效光催化CO₂还原[J]. 催化学报, 2023, 44(1): 146-159.