Electroreduction of air-level CO2 with high conversion efficiency

doi:10.1016/S1872-2067(21)63988-8

Abstract

Abstract:

The electrochemical conversion of carbon dioxide (CO₂) has been attracting increasingly research interest in the past decade, with the ultimate goal of utilizing electricity from renewable energy to realize carbon neutrality, as well as economic and energy benefits. Nonetheless, the capture and concentrating of CO₂ cost a substantial portion of energy, while almost all the reported researches showed CO₂ electroreduction under high concentrations of (typically pure) CO₂ reactants, and only very few recent studies have investigated the capability of applying low CO₂ concentrations (such as ~10% in flue gases). In this work, we first demonstrated the electroreduction of 0.03% CO₂ (in helium) in a homemade gas-phase electrochemical electrolyzer, using a low-cost copper (Cu) or nanoscale copper (nano-Cu) catalyst. Mixed with steam, the gas-phase CO₂ was directly delivered onto the gas-solid interface with the Cu catalyst and reduced to CO, without the need/constraint of being adsorbed by aqueous solution or alkaline electrolytes. By tuning the catalyst and experimental parameters, the conversion efficiency of CO₂ reached as high as ~95%. Furthermore, we demonstrated the direct electroreduction of 0.04% CO₂ from real air sample with an optimized conversion efficiency of ~79%, suggesting a promising perspective of the electroreduction approach toward direct CO₂ conversion.

Key words: CO₂ conversion, Electrocatalysis, Low concentration CO₂, Flow rate, Conversion efficiency

Yangshen Chen, Miao Kan, Shuai Yan, Junbo Zhang, Kunhao Liu, Yaqin Yan, Anxiang Guan, Ximeng Lv, Linping Qian, Gengfeng Zheng. Electroreduction of air-level CO₂ with high conversion efficiency[J]. Chinese Journal of Catalysis, 2022, 43(7): 1703-1709.

×
share this article

Add to citation manager EndNote|Ris|BibTeX

URL: https://www.cjcatal.com/EN/10.1016/S1872-2067(21)63988-8

https://www.cjcatal.com/EN/Y2022/V43/I7/1703

Figures/Tables 5

Fig. 1. Schematic illustration of the CO2 conversion at low concentration (0.03% CO2 in He or 0.04% CO2 in air) with a homemade gas-phase electrochemical reactor.

Fig. 2. SEM images of Cu film (a) and nano-Cu film (b); XRD patterns (c) and double-layer capacitance (d) of Cu film and nano-Cu film.

Fig. 3. (a) LSV curves of Cu film in H2O, 1 mol/L KHCO3 and 1 mol/L KOH electrolyte with the flow rate of 4 mL·min-1 and electrolyzer length of 3 cm. CO2 conversion and product in H2O (b), 1 mol/L KHCO3 (c) and 1 mol/L KOH (d) at different potentials.

Fig. 4. (a) LSV curves of Cu film and nano Cu film in 1 mol/L KHCO3 with the length of 6 cm; CO2 conversion and product of Cu film (b) and nano-Cu film (c) with applied voltage of ?3.5 V at different flow rate; (d) Comparison of CO2 conversion for Cu film and nano-Cu film at different flow rate.

Fig. 5. (a) CO2 conversion and product of Cu film in 1 mol/L KHCO3 at -3.5 V with the length of 4 cm. (b) Comparison of CO2 conversion for Cu film with 4 and 6 cm at different flow rates. (c) The stability of CO2 conversion at -3.5 V for Cu film and corresponding current density curve. (d) CO2 conversion and product of Cu film in 1 mol/L KHCO3 at -3.5 V with the length of 6 cm in air. (e) Comparison of CO2 conversion of our work with previous literatures.

References

[1]	S. Jin, Z. Hao, K. Zhang, Z. Yan, J. Chen, Angew. Chem. Int. Ed., 2021, 60, 20627-20648.
[2]	Y. Hori, K. Kikuchi, A. Murata, S. Suzuki, Chem. Lett., 1986, 897-898.
[3]	Y. Huang, X. Mao, G. Yuan, D. Zhang, B. Pan, J. Deng, Y. Shi, N. Han, C. Li, L. Zhang, L. Wang, L. He, Y. Li, Y. Li, Angew. Chem. Int. Ed., 2021, 60, 15844-15848.
[4]	Q. Hu, Z. Han, X. Wang, G. Li, Z. Wang, X. Huang, H. Yang, X. Ren, Q. Zhang, J. Liu, C. He, Angew. Chem. Int. Ed., 2020, 59, 19054-19059.
[5]	D. Gao, T. Liu, G. Wang, X. Bao, ACS Energy Lett., 2021, 6, 713-727.
[6]	J. Fan, X. Zhao, X. Mao, J. Xu, N. Han, H. Yang, B. Pan, Y. Li, L. Wang, Y. Li, Adv. Mater., 2021, 33, 2100910.
[7]	W. Yang, H.-J. Wang, R.-R. Liu, J.-W. Wang, C. Zhang, C. Li, D.-C. Zhong, T.-B. Lu, Angew. Chem. Int. Ed., 2021, 60, 409-414
[8]	H. Yang, Y. Wu, G. Li, Q. Lin, Q. Hu, Q. Zhang, J. Liu, C. He, J. Am. Chem. Soc., 2019, 141, 12717-12723.
[9]	Y. Xu, J. P. Edwards, J. Zhong, C. P. O’Brien, C. M. Gabardo, C. McCallum, J. Li, C.-T. Dinh, E. H. Sargent, D. Sinton, Energy Environ. Sci., 2020, 13, 554-561.
[10]	Y. Cheng, J. Hou, P. Kang, ACS Energy Lett., 2021, 6, 3352-3358.
[11]	D. Kim, W. Choi, H. W. Lee, S. Y. Lee, Y. Choi, D. K. Lee, W. Kim, J. Na, U. Lee, Y. J. Hwang, D. H. Won, ACS Energy Lett., 2021, 6, 3488-3495.
[12]	H. H. Khoo, I. Halim, A. D. Handoko, J. CO₂ Util., 2020, 41, 101229.
[13]	H. Li, T. Liu, P. Wei, L. Lin, D. Gao, G. Wang, X. Bao, Angew. Chem. Int. Ed., 2021, 60, 14329-14333.
[14]	M. Wang, Q. Zhang, Q. Xie, L. Wan, Y. Zhao, X. Zhang, J. Luo, Nanoscale, 2020, 12, 17013-17019.
[15]	X. Rong, H.-J. Wang, X.-L. Lu, R. Si, T.-B. Lu, Angew. Chem. Int. Ed., 2020, 59, 1961-1965.
[16]	H. Liu, Y. Zhang, J. Luo, J. Energy Chem., 2020, 49, 51-58.
[17]	E. Huang Jianan, F. Li, A. Ozden, A. Sedighian Rasouli, F. P. García de Arquer, S. Liu, S. Zhang, M. Luo, X. Wang, Y. Lum, Y. Xu, K. Bertens, K. Miao Rui, C.-T. Dinh, D. Sinton, E. H. Sargent, Science, 2021, 372, 1074-1078.
[18]	J.-J. Lv, M. Jouny, W. Luc, W. Zhu, J.-J. Zhu, F. Jiao, Adv. Mater., 2018, 30, 1803111.
[19]	C.-T. Dinh, T. Burdyny, G. Kibria Md, A. Seifitokaldani, M. Gabardo Christine, F. P. García de Arquer, A. Kiani, P. Edwards Jonathan, P. De Luna, S. Bushuyev Oleksandr, C. Zou, R. Quintero-Bermudez, Y. Pang, D. Sinton, E. H. Sargent, Science, 2018, 360, 783-787.
[20]	Y. C. Li, D. Zhou, Z. Yan, R. H. Gonçalves, D. A. Salvatore, C. P. Berlinguette, T. E. Mallouk, ACS Energy Lett., 2016, 1, 1149-1153.
[21]	S. Ma, M. Sadakiyo, R. Luo, M. Heima, M. Yamauchi, P. J. A. Kenis, J. Power Sources, 2016, 301, 219-228.
[22]	E. Jeng, F. Jiao, React. Chem. Eng., 2020, 5, 1768-1775.

Electroreduction of air-level CO₂ with high conversion efficiency

RichHTML

PDF (PC)

Knowledge

Supporting Information

Abstract

Cite this article

share this article

share this article

Figures/Tables 5

References

Related Articles 15

Recommended Articles

Metrics

[1]	Xiaolong Tang, Feng Li, Fang Li, Yanbin Jiang, Changlin Yu. Single-atom catalysts for the photocatalytic and electrocatalytic synthesis of hydrogen peroxide [J]. Chinese Journal of Catalysis, 2023, 52(9): 79-98.
[2]	Ji Zhang, Aimin Yu, Chenghua Sun. Theoretical insights into heteronuclear dual metals on non-metal doped graphene for nitrogen reduction reaction [J]. Chinese Journal of Catalysis, 2023, 52(9): 263-270.
[3]	Jin-Nian Hu, Ling-Chan Tian, Haiyan Wang, Yang Meng, Jin-Xia Liang, Chun Zhu, Jun Li. Theoretical screening of single-atom electrocatalysts of MXene-supported 3d-metals for efficient nitrogen reduction [J]. Chinese Journal of Catalysis, 2023, 52(9): 252-262.
[4]	Yan Hong, Qi Wang, Ziwang Kan, Yushuo Zhang, Jing Guo, Siqi Li, Song Liu, Bin Li. Recent progress in advanced catalysts for electrochemical nitrogen reduction reaction to ammonia [J]. Chinese Journal of Catalysis, 2023, 52(9): 50-78.
[5]	Hui Gao, Gong Zhang, Dongfang Cheng, Yongtao Wang, Jing Zhao, Xiaozhi Li, Xiaowei Du, Zhi-Jian Zhao, Tuo Wang, Peng Zhang, Jinlong Gong. Steering electrochemical carbon dioxide reduction to alcohol production on Cu step sites [J]. Chinese Journal of Catalysis, 2023, 52(9): 187-195.
[6]	Xinyi Zou, Jun Gu. Strategies for efficient CO₂ electroreduction in acidic conditions [J]. Chinese Journal of Catalysis, 2023, 52(9): 14-31.
[7]	Bo Zhou, Jianqiao Shi, Yimin Jiang, Lei Xiao, Yuxuan Lu, Fan Dong, Chen Chen, Tehua Wang, Shuangyin Wang, Yuqin Zou. Enhanced dehydrogenation kinetics for ascorbic acid electrooxidation with ultra-low cell voltage and large current density [J]. Chinese Journal of Catalysis, 2023, 50(7): 372-380.
[8]	Yuannan Wang, Lina Wang, Kexin Zhang, Jingyao Xu, Qiannan Wu, Zhoubing Xie, Wei An, Xiao Liang, Xiaoxin Zou. Electrocatalytic water splitting over perovskite oxide catalysts [J]. Chinese Journal of Catalysis, 2023, 50(7): 109-125.
[9]	Na Zhou, Jiazhi Wang, Ning Zhang, Zhi Wang, Hengguo Wang, Gang Huang, Di Bao, Haixia Zhong, Xinbo Zhang. Defect-rich Cu@CuTCNQ composites for enhanced electrocatalytic nitrate reduction to ammonia [J]. Chinese Journal of Catalysis, 2023, 50(7): 324-333.
[10]	Sang Eon Jun, Sungkyun Choi, Jaehyun Kim, Ki Chang Kwon, Sun Hwa Park, Ho Won Jang. Non-noble metal single atom catalysts for electrochemical energy conversion reactions [J]. Chinese Journal of Catalysis, 2023, 50(7): 195-214.
[11]	Qing Niu, Linhua Mi, Wei Chen, Qiujun Li, Shenghong Zhong, Yan Yu, Liuyi Li. Review of covalent organic frameworks for single-site photocatalysis and electrocatalysis [J]. Chinese Journal of Catalysis, 2023, 50(7): 45-82.
[12]	Jingxiang Low, Chao Zhang, Ferdi Karadas, Yujie Xiong. Photocatalytic CO₂ conversion: Beyond the earth [J]. Chinese Journal of Catalysis, 2023, 50(7): 1-5.
[13]	Cheng-Feng Du, Erhai Hu, Hong Yu, Qingyu Yan. Strategies for local electronic structure engineering of two-dimensional electrocatalysts [J]. Chinese Journal of Catalysis, 2023, 48(5): 1-14.
[14]	Qi-Ni Zhan, Ting-Yu Shuai, Hui-Min Xu, Chen-Jin Huang, Zhi-Jie Zhang, Gao-Ren Li. Syntheses and applications of single-atom catalysts for electrochemical energy conversion reactions [J]. Chinese Journal of Catalysis, 2023, 47(4): 32-66.
[15]	Yan Wei, Ruizhi Duan, Qiaolan Zhang, Youzhi Cao, Jinyuan Wang, Bing Wang, Wenrui Wan, Chunyan Liu, Jiazang Chen, Hong Gao, Huanwang Jing. Photoelectrocatalytic reduction of CO₂ catalyzed by TiO₂/TiN nanotube heterojunction: Nitrogen assisted active hydrogen mechanism [J]. Chinese Journal of Catalysis, 2023, 47(4): 243-253.