Latest development of ultrathin two-dimensional materials for photocatalytic and electrocatalytic CO2 reduction

被引:0
作者
Ren J. [1 ]
Tan L. [1 ]
Zhao Y. [1 ,2 ]
Song Y. [1 ]
机构
[1] State Key Laboratory of Chemical Resource Engineering, Beijing University of Chemical Technology, Beijing
[2] College of Chemistry, Beijing University of Chemical Technology, Beijing
来源
Zhao, Yufei (zhaoyufei@mail.buct.edu.cn); Song, Yufei (songyf@mail.buct.edu.cn) | 1600年 / Materials China卷 / 72期
关键词
Carbon dioxide; Catalysis; Electrocatalysis; Photocatalysis; Reduction; Two-dimensional materials;
D O I
10.11949/0438-1157.20201297
中图分类号
学科分类号
摘要
Energy shortage and environmental pollution are huge challenges for all mankind. The over-dependence on fossil fuels has led to a sharp increase in CO2 emissions. How to transform excessive greenhouse gases into fuels or other high-value chemicals through clean means has become a global research topic. Over the past few decades, solar and electrochemical approaches to reducing carbon dioxide have proved to be as both clean and effective methods to reduce the global carbon footprint and realize the efficient utilization of fossil resources. In recent years, the excellent performance of ultrathin two-dimensional materials (such as hydrotalcite, oxide, perovskite, etc.) in the field of catalysis has attracted a lot of attention. The electronic structure of two-dimensional materials is more adjustable and can be modified on its surface, which provides more opportunities for them to play a role in more catalytic reactions. This article summarizes the frontier progress of ultra-thin two-dimensional related materials in photocatalysis, photothermal/photovoltaic/photovoltaic-electrocatalysis, and electrocatalytic reduction of CO2 in recent years, and summarizes their modulation rules, which will provide reference for the design of high-efficiency optical and electrocatalysts in the future. © 2021, Editorial Board of CIESC Journal. All right reserved.
引用
收藏
页码:398 / 424
页数:26
相关论文
共 137 条
[1]  
McCollum D, Bauer N, Calvin K, Et al., Fossil resource and energy security dynamics in conventional and carbon-constrained worlds [J], Climatic Change, 123, 3, pp. 413-426, (2013)
[2]  
Davis S J, Caldeira K, Matthews H D., Future CO<sub>2</sub> emissions and climate change from existing energy infrastructure, Science, 329, 5997, pp. 1330-1333, (2010)
[3]  
Shi J F, Jiang Y J, Jiang Z Y, Et al., Enzymatic conversion of carbon dioxide, Chemical Society Reviews, 44, 17, pp. 5981-6000, (2015)
[4]  
Zhu D D, Liu J L, Qiao S Z., Recent advances in inorganic heterogeneous electrocatalysts for reduction of carbon dioxide, Advanced Materials, 28, 18, pp. 3423-3452, (2016)
[5]  
Habisreutinger S N, Schmidt-Mende L, Stolarczyk J K., Photocatalytic reduction of CO<sub>2</sub> on TiO<sub>2</sub> and other semiconductors, Angewandte Chemie International Edition, 52, 29, pp. 7372-7408, (2013)
[6]  
Grodkowski J, Neta P., Copper-catalyzed radiolytic reduction of CO<sub>2</sub> to CO in aqueous solutions, The Journal of Physical Chemistry B, 105, 21, pp. 4967-4972, (2001)
[7]  
Wang W, Wang S P, Ma X B, Et al., Recent advances in catalytic hydrogenation of carbon dioxide, Chemical Society Reviews, 40, 7, pp. 3703-3727, (2011)
[8]  
Klankermayer J, Wesselbaum S, Beydoun K, Et al., Selective catalytic synthesis using the combination of carbon dioxide and hydrogen: catalytic chess at the interface of energy and chemistry, Angewandte Chemie International Edition, 55, 26, pp. 7296-7343, (2016)
[9]  
Sun Z Y, Ma T, Tao H C, Et al., Fundamentals and challenges of electrochemical CO<sub>2</sub> reduction using two-dimensional materials, Chem, 3, 4, pp. 560-587, (2017)
[10]  
Grills D C, Matsubara Y, Kuwahara Y, Et al., Electrocatalytic CO<sub>2</sub> reduction with a homogeneous catalyst in ionic liquid: high catalytic activity at low overpotential, The Journal of Physical Chemistry Letters, 5, 11, pp. 2033-2038, (2014)
12345678910