Your search keyword '"Chen, Chunjun"' showing total 26 results

1. Cooperation of Different Active Sites to Promote CO2 Electroreduction to Multi‐carbon Products at Ampere‐Level.

Author

Zhou, Dawei, Chen, Chunjun, Zhang, Yichi, Wang, Min, Han, Shitao, Dong, Xue, Yao, Ting, Jia, Shuaiqiang, He, Mingyuan, Wu, Haihong, and Han, Buxing

Subjects

*CARBON offsetting, *ELECTROLYTIC reduction, *DENSITY functional theory, *SUSTAINABLE chemistry, *COPPER

Abstract

Electroreduction of CO2 to C2+ products provides a promising strategy for reaching the goal of carbon neutrality. However, achieving high selectivity of C2+ products at high current density remains a challenge. In this work, we designed and prepared a multi‐sites catalyst, in which Pd was atomically dispersed in Cu (Pd−Cu). It was found that the Pd−Cu catalyst had excellent performance for producing C2+ products from CO2 electroreduction. The Faradaic efficiency (FE) of C2+ products could be maintained at approximately 80.8 %, even at a high current density of 0.8 A cm−2 for at least 20 hours. In addition, the FE of C2+ products was above 70 % at 1.4 A cm−2. Experiments and density functional theory (DFT) calculations revealed that the catalyst had three distinct catalytic sites. These three active sites allowed for efficient conversion of CO2, water dissociation, and CO conversion, ultimately leading to high yields of C2+ products. [ABSTRACT FROM AUTHOR]

Published

2024

2. Cooperation of Different Active Sites to Promote CO2 Electroreduction to Multi‐carbon Products at Ampere‐Level.

Author

Zhou, Dawei, Chen, Chunjun, Zhang, Yichi, Wang, Min, Han, Shitao, Dong, Xue, Yao, Ting, Jia, Shuaiqiang, He, Mingyuan, Wu, Haihong, and Han, Buxing

Subjects

*CARBON offsetting, *ELECTROLYTIC reduction, *DENSITY functional theory, *SUSTAINABLE chemistry, *COPPER

Abstract

Electroreduction of CO2 to C2+ products provides a promising strategy for reaching the goal of carbon neutrality. However, achieving high selectivity of C2+ products at high current density remains a challenge. In this work, we designed and prepared a multi‐sites catalyst, in which Pd was atomically dispersed in Cu (Pd−Cu). It was found that the Pd−Cu catalyst had excellent performance for producing C2+ products from CO2 electroreduction. The Faradaic efficiency (FE) of C2+ products could be maintained at approximately 80.8 %, even at a high current density of 0.8 A cm−2 for at least 20 hours. In addition, the FE of C2+ products was above 70 % at 1.4 A cm−2. Experiments and density functional theory (DFT) calculations revealed that the catalyst had three distinct catalytic sites. These three active sites allowed for efficient conversion of CO2, water dissociation, and CO conversion, ultimately leading to high yields of C2+ products. [ABSTRACT FROM AUTHOR]

Published

2024

3. Boosting the Productivity of Electrochemical CO2 Reduction to Multi‐Carbon Products by Enhancing CO2 Diffusion through a Porous Organic Cage.

Author

Chen, Chunjun, Yan, Xupeng, Wu, Yahui, Liu, Shoujie, Zhang, Xiudong, Sun, Xiaofu, Zhu, Qinggong, Wu, Haihong, and Han, Buxing

Subjects

*SURFACE diffusion, *CARBON dioxide, *ELECTROLYTIC reduction

Abstract

Electroreduction of CO2 into valuable fuels and feedstocks offers a promising way for CO2 utilization. However, the commercialization is limited by the low productivity. Here, we report a strategy to enhance the productivity of CO2 electroreduction by improving diffusion of CO2 to the surface of catalysts using porous organic cages (POCs) as an additive. It was noted that the Faradaic efficiency (FE) of C2+ products could reach 76.1 % with a current density of 1.7 A cm−2 when Cu‐nanorod(nr)/CC3 (one of the POCs) was used, which were much higher than that using Cu‐nr. Detailed studies demonstrated that the hydrophobic pores of CC3 can adsorb a large amount of CO2 for the reaction, and the diffusion of CO2 in the CC3 to the nanocatalyst surface is easier than that in the liquid electrolyte. Thus, more CO2 molecules make contact with the nanocatalysts in the presence of CC3, enhancing CO2 reduction and inhibiting generation of H2. [ABSTRACT FROM AUTHOR]

Published

2022

4. Boosting the Productivity of Electrochemical CO2 Reduction to Multi‐Carbon Products by Enhancing CO2 Diffusion through a Porous Organic Cage.

Author

Chen, Chunjun, Yan, Xupeng, Wu, Yahui, Liu, Shoujie, Zhang, Xiudong, Sun, Xiaofu, Zhu, Qinggong, Wu, Haihong, and Han, Buxing

Subjects

*SURFACE diffusion, *CARBON dioxide, *ELECTROLYTIC reduction

Abstract

Electroreduction of CO2 into valuable fuels and feedstocks offers a promising way for CO2 utilization. However, the commercialization is limited by the low productivity. Here, we report a strategy to enhance the productivity of CO2 electroreduction by improving diffusion of CO2 to the surface of catalysts using porous organic cages (POCs) as an additive. It was noted that the Faradaic efficiency (FE) of C2+ products could reach 76.1 % with a current density of 1.7 A cm−2 when Cu‐nanorod(nr)/CC3 (one of the POCs) was used, which were much higher than that using Cu‐nr. Detailed studies demonstrated that the hydrophobic pores of CC3 can adsorb a large amount of CO2 for the reaction, and the diffusion of CO2 in the CC3 to the nanocatalyst surface is easier than that in the liquid electrolyte. Thus, more CO2 molecules make contact with the nanocatalysts in the presence of CC3, enhancing CO2 reduction and inhibiting generation of H2. [ABSTRACT FROM AUTHOR]

Published

2022

5. Boosting CO2 Electroreduction over a Cadmium Single‐Atom Catalyst by Tuning of the Axial Coordination Structure.

Author

Wu, Yahui, Chen, Chunjun, Yan, Xupeng, Sun, Xiaofu, Zhu, Qinggong, Li, Pengsong, Li, Yiming, Liu, Shoujie, Ma, Jingyuan, Huang, Yuying, and Han, Buxing

Subjects

*ELECTROLYTIC reduction, *CATALYSTS, *HYDROGEN evolution reactions, *ACTIVATION energy, *CADMIUM, *COORDINATION polymers, *ELECTROLYSIS

Abstract

Guided by first‐principles calculations, it was found that Cd single‐atom catalysts (SACs) have excellent performance in activating CO2, and the introduction of axial coordination structure to Cd SACs cannot only further decrease the free energy barrier of CO2 reduction, but also suppress the hydrogen evolution reaction (HER). Based on the above discovery, we designed and synthesized a novel Cd SAC that comprises an optimized CdN4S1 moiety incorporated in a carbon matrix. It was shown that the catalyst exhibited outstanding performance in CO2 electroreduction to CO. The faradaic efficiency (FE) of CO could reach up to 99.7 % with a current density of 182.2 mA cm−2 in a H‐type electrolysis cell, and the turnover frequency (TOF) value could achieve 73000 h−1, which was much higher than that reported to date. This work shows a successful example of how to design highly efficient catalysts guided by theoretical calculations. [ABSTRACT FROM AUTHOR]

Published

2021

6. Boosting CO2 Electroreduction over a Cadmium Single‐Atom Catalyst by Tuning of the Axial Coordination Structure.

Author

Wu, Yahui, Chen, Chunjun, Yan, Xupeng, Sun, Xiaofu, Zhu, Qinggong, Li, Pengsong, Li, Yiming, Liu, Shoujie, Ma, Jingyuan, Huang, Yuying, and Han, Buxing

Subjects

*HYDROGEN evolution reactions, *ELECTROLYTIC reduction, *CATALYSTS, *ACTIVATION energy, *CADMIUM, *COORDINATION polymers, *ELECTROLYSIS

Abstract

Guided by first‐principles calculations, it was found that Cd single‐atom catalysts (SACs) have excellent performance in activating CO2, and the introduction of axial coordination structure to Cd SACs cannot only further decrease the free energy barrier of CO2 reduction, but also suppress the hydrogen evolution reaction (HER). Based on the above discovery, we designed and synthesized a novel Cd SAC that comprises an optimized CdN4S1 moiety incorporated in a carbon matrix. It was shown that the catalyst exhibited outstanding performance in CO2 electroreduction to CO. The faradaic efficiency (FE) of CO could reach up to 99.7 % with a current density of 182.2 mA cm−2 in a H‐type electrolysis cell, and the turnover frequency (TOF) value could achieve 73000 h−1, which was much higher than that reported to date. This work shows a successful example of how to design highly efficient catalysts guided by theoretical calculations. [ABSTRACT FROM AUTHOR]

Published

2021

7. Highly Efficient Electroreduction of CO2 to C2+ Alcohols on Heterogeneous Dual Active Sites.

Author

Chen, Chunjun, Yan, Xupeng, Liu, Shoujie, Wu, Yahui, Wan, Qiang, Sun, Xiaofu, Zhu, Qinggong, Liu, Huizhen, Ma, Jun, Zheng, Lirong, Wu, Haihong, and Han, Buxing

Subjects

*ELECTROLYTIC reduction, *LIQUID fuels, *ETHANOL as fuel, *ALCOHOL, *QUANTUM dots, *PROPANOLS

Abstract

Electroreduction of CO2 to liquid fuels such as ethanol and n‐propanol, powered by renewable electricity, offers a promising strategy for controlling the global carbon balance and addressing the need for the storage of intermittent renewable energy. In this work, we discovered that the composite composed of nitrogen‐doped graphene quantum dots (NGQ) on CuO‐derived Cu nanorods (NGQ/Cu‐nr) was an outstanding electrocatalyst for the reduction of CO2 to ethanol and n‐propanol. The Faradaic efficiency (FE) of C2+ alcohols could reach 52.4 % with a total current density of 282.1 mA cm−2. This is the highest FE for C2+ alcohols with a commercial current density to date. Control experiments and DFT studies show that the NGQ/Cu‐nr could provide dual catalytic active sites and could stabilize the CH2CHO intermediate to enhance the FE of alcohols significantly through further carbon protonation. The NGQ and Cu‐nr had excellent synergistic effects for accelerating the reduction of CO2 to alcohols. [ABSTRACT FROM AUTHOR]

Published

2020

8. Highly Efficient Electroreduction of CO2 to C2+ Alcohols on Heterogeneous Dual Active Sites.

Author

Chen, Chunjun, Yan, Xupeng, Liu, Shoujie, Wu, Yahui, Wan, Qiang, Sun, Xiaofu, Zhu, Qinggong, Liu, Huizhen, Ma, Jun, Zheng, Lirong, Wu, Haihong, and Han, Buxing

Subjects

*ELECTROLYTIC reduction, *ETHANOL as fuel, *LIQUID fuels, *ALCOHOL, *QUANTUM dots, *PROPANOLS

Abstract

Electroreduction of CO2 to liquid fuels such as ethanol and n‐propanol, powered by renewable electricity, offers a promising strategy for controlling the global carbon balance and addressing the need for the storage of intermittent renewable energy. In this work, we discovered that the composite composed of nitrogen‐doped graphene quantum dots (NGQ) on CuO‐derived Cu nanorods (NGQ/Cu‐nr) was an outstanding electrocatalyst for the reduction of CO2 to ethanol and n‐propanol. The Faradaic efficiency (FE) of C2+ alcohols could reach 52.4 % with a total current density of 282.1 mA cm−2. This is the highest FE for C2+ alcohols with a commercial current density to date. Control experiments and DFT studies show that the NGQ/Cu‐nr could provide dual catalytic active sites and could stabilize the CH2CHO intermediate to enhance the FE of alcohols significantly through further carbon protonation. The NGQ and Cu‐nr had excellent synergistic effects for accelerating the reduction of CO2 to alcohols. [ABSTRACT FROM AUTHOR]

Published

2020

9. Boosting CO2 Electroreduction on N,P‐Co‐doped Carbon Aerogels.

Author

Chen, Chunjun, Sun, Xiaofu, Yan, Xupeng, Wu, Yahui, Liu, Huizhen, Zhu, Qinggong, Bediako, Bernard Baffour Asare, and Han, Buxing

Subjects

*AEROGELS, *ELECTROLYTIC reduction, *HYDROGEN evolution reactions, *DENSITY currents, *CHARGE exchange, *RADICAL anions

Abstract

Electroreduction of CO2 to CO powered by renewable electricity is a possible alternative to synthesizing CO from fossil fuel. However, it is very hard to achieve high current density at high faradaic efficiency (FE). Here, the first use of N,P‐co‐doped carbon aerogels (NPCA) to boost CO2 reduction to CO is presented. The FE of CO could reach 99.1 % with a partial current density of −143.6 mA cm−2, which is one of the highest current densities to date. NPCA has higher electrochemical active area and overall electronic conductivity than that of N‐ or P‐doped carbon aerogels, which favors electron transfer from CO2 to its radical anion or other key intermediates. By control experiments and theoretical calculations, it is found that the pyridinic N was very active for CO2 reduction to CO, and co‐doping of P with N hinder the hydrogen evolution reaction (HER) significantly, and thus the both current density and FE are very high. [ABSTRACT FROM AUTHOR]

Published

2020

10. Boosting CO2 Electroreduction on N,P‐Co‐doped Carbon Aerogels.

Author

Chen, Chunjun, Sun, Xiaofu, Yan, Xupeng, Wu, Yahui, Liu, Huizhen, Zhu, Qinggong, Bediako, Bernard Baffour Asare, and Han, Buxing

Subjects

*AEROGELS, *ELECTROLYTIC reduction, *HYDROGEN evolution reactions, *DENSITY currents, *CHARGE exchange, *RADICAL anions

Abstract

Electroreduction of CO2 to CO powered by renewable electricity is a possible alternative to synthesizing CO from fossil fuel. However, it is very hard to achieve high current density at high faradaic efficiency (FE). Here, the first use of N,P‐co‐doped carbon aerogels (NPCA) to boost CO2 reduction to CO is presented. The FE of CO could reach 99.1 % with a partial current density of −143.6 mA cm−2, which is one of the highest current densities to date. NPCA has higher electrochemical active area and overall electronic conductivity than that of N‐ or P‐doped carbon aerogels, which favors electron transfer from CO2 to its radical anion or other key intermediates. By control experiments and theoretical calculations, it is found that the pyridinic N was very active for CO2 reduction to CO, and co‐doping of P with N hinder the hydrogen evolution reaction (HER) significantly, and thus the both current density and FE are very high. [ABSTRACT FROM AUTHOR]

Published

2020

11. Aqueous CO2 Reduction with High Efficiency Using α‐Co(OH)2‐Supported Atomic Ir Electrocatalysts.

Author

Sun, Xiaofu, Chen, Chunjun, Liu, Shoujie, Hong, Song, Zhu, Qinggong, Qian, Qingli, Han, Buxing, Zhang, Jing, and Zheng, Lirong

Subjects

*ELECTROCATALYSTS, *CATALYTIC activity, *RADICAL anions, *CHARGE exchange, *ELECTROLYTIC reduction, *AQUEOUS electrolytes

Abstract

Electrochemical reduction of CO2 into energy‐dense chemical feedstock and fuels provides an attractive pathway to sustainable energy storage and artificial carbon cycle. Herein, we report the first work to use atomic Ir electrocatalyst for CO2 reduction. By using α‐Co(OH)2 as the support, the faradaic efficiency of CO could reach 97.6 % with a turnover frequency (TOF) of 38290 h−1 in aqueous electrolyte, which is the highest TOF up to date. The electrochemical active area is 23.4‐times higher than Ir nanoparticles (2 nm), which is highly conductive and favors electron transfer from CO2 to its radical anion (CO2.−). Moreover, the more efficient stabilization of CO2.− intermediate and easy charge transfer makes the atomic Ir electrocatalyst facilitate CO production. Hence, α‐Co(OH)2‐supported atomic Ir electrocatalysts show enhanced CO2 activity and stability. High‐density atomic Ir supported on α‐Co(OH)2 had outstanding performance for CO2 reduction to CO. The faradaic efficiency can reach 97.6 % with a TOF of 38 290 h−1. The high catalytic activity is attributed to more active sites for CO2 adsorption and activation and the higher efficiency in stabilizing the CO2.− intermediate. [ABSTRACT FROM AUTHOR]

Published

2019

12. Aqueous CO2 Reduction with High Efficiency Using α‐Co(OH)2‐Supported Atomic Ir Electrocatalysts.

Author

Sun, Xiaofu, Chen, Chunjun, Liu, Shoujie, Hong, Song, Zhu, Qinggong, Qian, Qingli, Han, Buxing, Zhang, Jing, and Zheng, Lirong

Subjects

*ELECTROLYTIC reduction, *CARBON dioxide reduction, *ELECTROCATALYSTS, *CARBON cycle, *AQUEOUS solutions

Abstract

Electrochemical reduction of CO2 into energy‐dense chemical feedstock and fuels provides an attractive pathway to sustainable energy storage and artificial carbon cycle. Herein, we report the first work to use atomic Ir electrocatalyst for CO2 reduction. By using α‐Co(OH)2 as the support, the faradaic efficiency of CO could reach 97.6 % with a turnover frequency (TOF) of 38290 h−1 in aqueous electrolyte, which is the highest TOF up to date. The electrochemical active area is 23.4‐times higher than Ir nanoparticles (2 nm), which is highly conductive and favors electron transfer from CO2 to its radical anion (CO2.−). Moreover, the more efficient stabilization of CO2.− intermediate and easy charge transfer makes the atomic Ir electrocatalyst facilitate CO production. Hence, α‐Co(OH)2‐supported atomic Ir electrocatalysts show enhanced CO2 activity and stability. [ABSTRACT FROM AUTHOR]

Published

2019

13. Polymer Modification Strategy to Modulate Reaction Microenvironment for Enhanced CO2 Electroreduction to Ethylene.

Author

Deng, Ting, Jia, Shuaiqiang, Chen, Chunjun, Jiao, Jiapeng, Chen, Xiao, Xue, Cheng, Xia, Wei, Xing, Xueqing, Zhu, Qinggong, Wu, Haihong, He, Mingyuan, and Han, Buxing

Subjects

*POLYTEF, *HYDROPHOBIC surfaces, *STANDARD hydrogen electrode, *CARBON dioxide reduction, *ELECTROLYTIC reduction, *ETHYLENE, *SUPERHYDROPHOBIC surfaces

Abstract

Modulation of the microenvironment on the electrode surface is one of the effective means to improve the efficiency of electrocatalytic carbon dioxide reduction (eCO2RR). To achieve high conversion rates, the phase boundary at the electrode surface should be finely controlled to overcome the limitation of CO2 solubility in the aqueous electrolyte. Herein, we developed a simple and efficient method to structure electrocatalyst with a superhydrophobic surface microenvironment by one‐step co‐electrodeposition of Cu and polytetrafluoroethylene (PTFE) on carbon paper. The super‐hydrophobic Cu‐based electrode displayed a high ethylene (C2H4) selectivity with a Faraday efficiency (FE) of 67.3 % at −1.25 V vs. reversible hydrogen electrode (RHE) in an H‐type cell, which is 2.5 times higher than a regular Cu electrode without PTFE. By using PTFE as a surface modifier, the activity of eCO2RR is enhanced and water (proton) adsorption is inhibited. This strategy has the potential to be applied to other gas‐conversion electrocatalysts. [ABSTRACT FROM AUTHOR]

Published

2024

14. Polymer Modification Strategy to Modulate Reaction Microenvironment for Enhanced CO2 Electroreduction to Ethylene.

Author

Deng, Ting, Jia, Shuaiqiang, Chen, Chunjun, Jiao, Jiapeng, Chen, Xiao, Xue, Cheng, Xia, Wei, Xing, Xueqing, Zhu, Qinggong, Wu, Haihong, He, Mingyuan, and Han, Buxing

Subjects

*POLYTEF, *HYDROPHOBIC surfaces, *STANDARD hydrogen electrode, *CARBON dioxide reduction, *ELECTROLYTIC reduction, *ETHYLENE, *SUPERHYDROPHOBIC surfaces

Abstract

Modulation of the microenvironment on the electrode surface is one of the effective means to improve the efficiency of electrocatalytic carbon dioxide reduction (eCO2RR). To achieve high conversion rates, the phase boundary at the electrode surface should be finely controlled to overcome the limitation of CO2 solubility in the aqueous electrolyte. Herein, we developed a simple and efficient method to structure electrocatalyst with a superhydrophobic surface microenvironment by one‐step co‐electrodeposition of Cu and polytetrafluoroethylene (PTFE) on carbon paper. The super‐hydrophobic Cu‐based electrode displayed a high ethylene (C2H4) selectivity with a Faraday efficiency (FE) of 67.3 % at −1.25 V vs. reversible hydrogen electrode (RHE) in an H‐type cell, which is 2.5 times higher than a regular Cu electrode without PTFE. By using PTFE as a surface modifier, the activity of eCO2RR is enhanced and water (proton) adsorption is inhibited. This strategy has the potential to be applied to other gas‐conversion electrocatalysts. [ABSTRACT FROM AUTHOR]

Published

2024

15. Selective and Efficient CO2 Electroreduction to Formate on Copper Electrodes Modified by Cationic Gemini Surfactants.

Author

Zhang, Xiudong, Yan, Xupeng, Chen, Peng, Zhang, Pei, Kang, Xinchen, Ma, Jun, Chen, Chunjun, and Han, Buxing

Subjects

*COPPER electrodes, *COPPER, *ELECTROLYTIC reduction, *NANOSTRUCTURED materials, *ENERGY consumption, *SURFACE active agents

Abstract

Electroreduction of CO2 into valuable chemicals and fuels is a promising strategy to mitigate energy and environmental problems. However, it usually suffers from unsatisfactory selectivity for a single product and inadequate electrochemical stability. Herein, we report the first work to use cationic Gemini surfactants as modifiers to boost CO2 electroreduction to formate. The selectivity, activity and stability of the catalysts can be all significantly enhanced by Gemini surfactant modification. The Faradaic efficiency (FE) of formate could reach up to 96 %, and the energy efficiency (EE) could achieve 71 % over the Gemini surfactants modified Cu electrode. In addition, the Gemini surfactants modified commercial Bi2O3 nanosheets also showed an excellent catalytic performance, and the FE of formate reached 91 % with a current density of 510 mA cm−2 using the flow cell. Detailed studies demonstrated that the double quaternary ammonium cations and alkyl chains of the Gemini surfactants played a crucial role in boosting electroreduction CO2, which can not only stabilize the key intermediate HCOO* but also provide an easy access for CO2. These observations could shine light on the rational design of organic modifiers for promoted CO2 electroreduction. [ABSTRACT FROM AUTHOR]

Published

2024

16. Selective and Efficient CO2 Electroreduction to Formate on Copper Electrodes Modified by Cationic Gemini Surfactants.

Author

Zhang, Xiudong, Yan, Xupeng, Chen, Peng, Zhang, Pei, Kang, Xinchen, Ma, Jun, Chen, Chunjun, and Han, Buxing

Subjects

*COPPER electrodes, *COPPER, *ELECTROLYTIC reduction, *NANOSTRUCTURED materials, *ENERGY consumption, *SURFACE active agents

Abstract

Electroreduction of CO2 into valuable chemicals and fuels is a promising strategy to mitigate energy and environmental problems. However, it usually suffers from unsatisfactory selectivity for a single product and inadequate electrochemical stability. Herein, we report the first work to use cationic Gemini surfactants as modifiers to boost CO2 electroreduction to formate. The selectivity, activity and stability of the catalysts can be all significantly enhanced by Gemini surfactant modification. The Faradaic efficiency (FE) of formate could reach up to 96 %, and the energy efficiency (EE) could achieve 71 % over the Gemini surfactants modified Cu electrode. In addition, the Gemini surfactants modified commercial Bi2O3 nanosheets also showed an excellent catalytic performance, and the FE of formate reached 91 % with a current density of 510 mA cm−2 using the flow cell. Detailed studies demonstrated that the double quaternary ammonium cations and alkyl chains of the Gemini surfactants played a crucial role in boosting electroreduction CO2, which can not only stabilize the key intermediate HCOO* but also provide an easy access for CO2. These observations could shine light on the rational design of organic modifiers for promoted CO2 electroreduction. [ABSTRACT FROM AUTHOR]

Published

2024

17. Synergy of Cu/C3N4 Interface and Cu Nanoparticles Dual Catalytic Regions in Electrolysis of CO to Acetic Acid.

Author

Yan, Xupeng, Zhang, Menglu, Chen, Yizhen, Wu, Yahui, Wu, Ruizhi, Wan, Qiang, Liu, Chunxiao, Zheng, Tingting, Feng, Rongjuan, Zhang, Jing, Chen, Chunjun, Xia, Chuan, Zhu, Qinggong, Sun, Xiaofu, Qian, Qingli, and Han, Buxing

Subjects

*COPPER, *ACETIC acid, *METALLIC surfaces, *SOLID electrolytes, *CARBON monoxide, *DENSITY functional theory, *ELECTROLYTIC reduction

Abstract

Electrochemical reduction reaction of carbon monoxide (CORR) offers a promising way to manufacture acetic acid directly from gaseous CO and water at mild condition. Herein, we discovered that the graphitic carbon nitride (g‐C3N4) supported Cu nanoparticles (Cu−CN) with the appropriate size showed a high acetate faradaic efficiency of 62.8 % with a partial current density of 188 mA cm−2 in CORR. In situ experimental and density functional theory calculation studies revealed that the Cu/C3N4 interface and metallic Cu surface synergistically promoted CORR into acetic acid. The generation of pivotal intermediate −*CHO is advantage around the Cu/C3N4 interface and migrated *CHO facilitates acetic acid generation on metallic Cu surface with promoted *CHO coverage. Moreover, continuous production of acetic acid aqueous solution was achieved in a porous solid electrolyte reactor, indicating the great potential of Cu−CN catalyst in the industrial application. [ABSTRACT FROM AUTHOR]

Published

2023

18. Synergy of Cu/C3N4 Interface and Cu Nanoparticles Dual Catalytic Regions in Electrolysis of CO to Acetic Acid.

Author

Yan, Xupeng, Zhang, Menglu, Chen, Yizhen, Wu, Yahui, Wu, Ruizhi, Wan, Qiang, Liu, Chunxiao, Zheng, Tingting, Feng, Rongjuan, Zhang, Jing, Chen, Chunjun, Xia, Chuan, Zhu, Qinggong, Sun, Xiaofu, Qian, Qingli, and Han, Buxing

Subjects

*COPPER, *ACETIC acid, *METALLIC surfaces, *SOLID electrolytes, *CARBON monoxide, *DENSITY functional theory, *ELECTROLYTIC reduction

Abstract

Electrochemical reduction reaction of carbon monoxide (CORR) offers a promising way to manufacture acetic acid directly from gaseous CO and water at mild condition. Herein, we discovered that the graphitic carbon nitride (g‐C3N4) supported Cu nanoparticles (Cu−CN) with the appropriate size showed a high acetate faradaic efficiency of 62.8 % with a partial current density of 188 mA cm−2 in CORR. In situ experimental and density functional theory calculation studies revealed that the Cu/C3N4 interface and metallic Cu surface synergistically promoted CORR into acetic acid. The generation of pivotal intermediate −*CHO is advantage around the Cu/C3N4 interface and migrated *CHO facilitates acetic acid generation on metallic Cu surface with promoted *CHO coverage. Moreover, continuous production of acetic acid aqueous solution was achieved in a porous solid electrolyte reactor, indicating the great potential of Cu−CN catalyst in the industrial application. [ABSTRACT FROM AUTHOR]

Published

2023

19. In Situ Periodic Regeneration of Catalyst during CO2 Electroreduction to C2+ Products.

Author

Xu, Liang, Ma, Xiaodong, Wu, Limin, Tan, Xingxing, Song, Xinning, Zhu, Qinggong, Chen, Chunjun, Qian, Qingli, Liu, Zhimin, Sun, Xiaofu, Liu, Shoujie, and Han, Buxing

Subjects

*COUPLING reactions (Chemistry), *CATALYSTS, *CARBON offsetting, *SURFACE structure, *OXIDATION states

Abstract

Developing electrocatalytic reactions with high‐efficiency can make important contributions to carbon neutrality. However, poor long‐term stability of catalysts is a bottleneck for its practical application. Herein, an "in situ periodic regeneration of catalyst (PR‐C)" strategy is proposed to give long‐term high efficiency of CO2 electroreduction to generate C2+ products over Cu catalyst by applying a positive potential pulse for a short time periodically in the halide‐containing electrolyte. The high Faradaic efficiency (81.2 %) and current density (22.6 mA cm−2) could be maintained completely at least 36 h, while the activity and selectivity decreased continuously without using the PR‐C method. Control experiments and operando characterization demonstrated that the surface structure and oxidation state of Cu could be recovered periodically by the PR‐C method, which was beneficial for CO2 activation and C−C coupling. [ABSTRACT FROM AUTHOR]

Published

2022

20. In Situ Periodic Regeneration of Catalyst during CO2 Electroreduction to C2+ Products.

Author

Xu, Liang, Ma, Xiaodong, Wu, Limin, Tan, Xingxing, Song, Xinning, Zhu, Qinggong, Chen, Chunjun, Qian, Qingli, Liu, Zhimin, Sun, Xiaofu, Liu, Shoujie, and Han, Buxing

Subjects

*COUPLING reactions (Chemistry), *CATALYSTS, *CARBON offsetting, *ELECTROLYTIC reduction, *SURFACE structure, *OXIDATION states, *CATALYTIC cracking

Abstract

Developing electrocatalytic reactions with high‐efficiency can make important contributions to carbon neutrality. However, poor long‐term stability of catalysts is a bottleneck for its practical application. Herein, an "in situ periodic regeneration of catalyst (PR‐C)" strategy is proposed to give long‐term high efficiency of CO2 electroreduction to generate C2+ products over Cu catalyst by applying a positive potential pulse for a short time periodically in the halide‐containing electrolyte. The high Faradaic efficiency (81.2 %) and current density (22.6 mA cm−2) could be maintained completely at least 36 h, while the activity and selectivity decreased continuously without using the PR‐C method. Control experiments and operando characterization demonstrated that the surface structure and oxidation state of Cu could be recovered periodically by the PR‐C method, which was beneficial for CO2 activation and C−C coupling. [ABSTRACT FROM AUTHOR]

Published

2022

21. Highly Efficient CO2 Electroreduction to Methanol through Atomically Dispersed Sn Coupled with Defective CuO Catalysts.

Author

Guo, Weiwei, Liu, Shoujie, Tan, Xingxing, Wu, Ruizhi, Yan, Xupeng, Chen, Chunjun, Zhu, Qinggong, Zheng, Lirong, Ma, Jingyuan, Zhang, Jing, Huang, Yuying, Sun, Xiaofu, and Han, Buxing

Subjects

*CATALYSTS, *TIN, *ELECTROLYTIC reduction, *METHANOL, *ACTIVATION energy, *DENSITY functional theory

Abstract

Using renewable electricity to drive CO2 electroreduction is an attractive way to achieve carbon‐neutral energy cycle and produce value‐added chemicals and fuels. As an important platform molecule and clean fuel, methanol requires 6‐electron transfer in the process of CO2 reduction. Currently, CO2 electroreduction to methanol suffers from poor efficiency and low selectivity. Herein, we report the first work to design atomically dispersed Sn site anchored on defective CuO catalysts for CO2 electroreduction to methanol. It exhibits high methanol Faradaic efficiency (FE) of 88.6 % with a current density of 67.0 mA cm−2 and remarkable stability in a H‐cell, which is the highest FE(methanol) with such high current density compared with the results reported to date. The atomic Sn site, adjacent oxygen vacancy and CuO support cooperate very well, leading to higher double‐layer capacitance, larger CO2 adsorption capacity and lower interfacial charge transfer resistance. Operando experiments and density functional theory calculations demonstrate that the catalyst is beneficial for CO2 activation via decreasing the energy barrier of *COOH dissociation to form *CO. The obtained key intermediate *CO is then bound to the Cu species for further reduction, leading to high selectivity toward methanol. [ABSTRACT FROM AUTHOR]

Published

2021

22. Highly Efficient CO2 Electroreduction to Methanol through Atomically Dispersed Sn Coupled with Defective CuO Catalysts.

Author

Guo, Weiwei, Liu, Shoujie, Tan, Xingxing, Wu, Ruizhi, Yan, Xupeng, Chen, Chunjun, Zhu, Qinggong, Zheng, Lirong, Ma, Jingyuan, Zhang, Jing, Huang, Yuying, Sun, Xiaofu, and Han, Buxing

Subjects

*CATALYSTS, *TIN, *COPPER oxide, *ELECTROLYTIC reduction, *METHANOL, *ACTIVATION energy

Abstract

Using renewable electricity to drive CO2 electroreduction is an attractive way to achieve carbon‐neutral energy cycle and produce value‐added chemicals and fuels. As an important platform molecule and clean fuel, methanol requires 6‐electron transfer in the process of CO2 reduction. Currently, CO2 electroreduction to methanol suffers from poor efficiency and low selectivity. Herein, we report the first work to design atomically dispersed Sn site anchored on defective CuO catalysts for CO2 electroreduction to methanol. It exhibits high methanol Faradaic efficiency (FE) of 88.6 % with a current density of 67.0 mA cm−2 and remarkable stability in a H‐cell, which is the highest FE(methanol) with such high current density compared with the results reported to date. The atomic Sn site, adjacent oxygen vacancy and CuO support cooperate very well, leading to higher double‐layer capacitance, larger CO2 adsorption capacity and lower interfacial charge transfer resistance. Operando experiments and density functional theory calculations demonstrate that the catalyst is beneficial for CO2 activation via decreasing the energy barrier of *COOH dissociation to form *CO. The obtained key intermediate *CO is then bound to the Cu species for further reduction, leading to high selectivity toward methanol. [ABSTRACT FROM AUTHOR]

Published

2021

23. Hollow Metal–Organic‐Framework‐Mediated In Situ Architecture of Copper Dendrites for Enhanced CO2 Electroreduction.

Author

Zhu, Qinggong, Yang, Dexin, Liu, Huizhen, Sun, Xiaofu, Chen, Chunjun, Bi, Jiahui, Liu, Jiyuan, Wu, Haihong, and Han, Buxing

Subjects

*ELECTROLYTIC reduction, *DENDRITIC crystals, *METAL-organic frameworks, *DENSITY currents, *ELECTROLYTES

Abstract

Electrocatalytic reduction of CO2 to a single product at high current densities and efficiencies remains a challenge. However, the conventional electrode preparation methods, such as drop‐casting, usually suffer from low intrinsic activity. Herein, we report a synthesis strategy for preparing heterogeneous electrocatalyst composed of 3D hierarchical Cu dendrites that derived from an in situ electrosynthesized hollow copper metal–organic framework (MOF), for which the preparation of the Cu‐MOF film took only 5 min. The synthesis strategy preferentially exposes active sites, which favor's the reduction of CO2 to formate. The current density could be as high as 102.1 mA cm−2 with a selectivity of 98.2 % in ionic‐liquid‐based electrolyte and a commonly used H‐type cell. [ABSTRACT FROM AUTHOR]

Published

2020

24. Hollow Metal–Organic‐Framework‐Mediated In Situ Architecture of Copper Dendrites for Enhanced CO2 Electroreduction.

Author

Zhu, Qinggong, Yang, Dexin, Liu, Huizhen, Sun, Xiaofu, Chen, Chunjun, Bi, Jiahui, Liu, Jiyuan, Wu, Haihong, and Han, Buxing

Subjects

*ELECTROLYTIC reduction, *DENDRITIC crystals, *METAL-organic frameworks, *DENSITY currents

Abstract

Electrocatalytic reduction of CO2 to a single product at high current densities and efficiencies remains a challenge. However, the conventional electrode preparation methods, such as drop‐casting, usually suffer from low intrinsic activity. Herein, we report a synthesis strategy for preparing heterogeneous electrocatalyst composed of 3D hierarchical Cu dendrites that derived from an in situ electrosynthesized hollow copper metal–organic framework (MOF), for which the preparation of the Cu‐MOF film took only 5 min. The synthesis strategy preferentially exposes active sites, which favor's the reduction of CO2 to formate. The current density could be as high as 102.1 mA cm−2 with a selectivity of 98.2 % in ionic‐liquid‐based electrolyte and a commonly used H‐type cell. [ABSTRACT FROM AUTHOR]

Published

2020

25. MoP Nanoparticles Supported on Indium‐Doped Porous Carbon: Outstanding Catalysts for Highly Efficient CO2 Electroreduction.

Author

Sun, Xiaofu, Lu, Lu, Zhu, Qinggong, Wu, Congyi, Yang, Dexin, Chen, Chunjun, and Han, Buxing

Subjects

*DOPING agents (Chemistry), *NANOPARTICLES, *INDIUM, *CATALYSTS, *ELECTROLYTIC reduction

Abstract

Abstract: Electrochemical reduction of CO2 into value‐added product is an interesting area. MoP nanoparticles supported on porous carbon were synthesized using metal–organic frameworks as the carbon precursor, and initial work on CO2 electroreduction using the MoP‐based catalyst were carried out. It was discovered that MoP nanoparticles supported on In‐doped porous carbon had outstanding performance for CO2 reduction to formic acid. The Faradaic efficiency and current density could reach 96.5 % and 43.8 mA cm−2, respectively, when using ionic liquid 1‐butyl‐3‐methylimidazolium hexafluorophosphate as the supporting electrolyte. The current density is higher than those reported up to date with very high Faradaic efficiency. The MoP nanoparticles and the doped In2O3 cooperated very well in catalyzing the CO2 electroreduction. [ABSTRACT FROM AUTHOR]

Published

2018

26. MoP Nanoparticles Supported on Indium‐Doped Porous Carbon: Outstanding Catalysts for Highly Efficient CO2 Electroreduction.

Author

Sun, Xiaofu, Lu, Lu, Zhu, Qinggong, Wu, Congyi, Yang, Dexin, Chen, Chunjun, and Han, Buxing

Subjects

*INDIUM compounds, *NANOPARTICLES, *CATALYSTS, *CARBON dioxide, *ELECTROLYTIC reduction

Abstract

Abstract: Electrochemical reduction of CO2 into value‐added product is an interesting area. MoP nanoparticles supported on porous carbon were synthesized using metal–organic frameworks as the carbon precursor, and initial work on CO2 electroreduction using the MoP‐based catalyst were carried out. It was discovered that MoP nanoparticles supported on In‐doped porous carbon had outstanding performance for CO2 reduction to formic acid. The Faradaic efficiency and current density could reach 96.5 % and 43.8 mA cm−2, respectively, when using ionic liquid 1‐butyl‐3‐methylimidazolium hexafluorophosphate as the supporting electrolyte. The current density is higher than those reported up to date with very high Faradaic efficiency. The MoP nanoparticles and the doped In2O3 cooperated very well in catalyzing the CO2 electroreduction. [ABSTRACT FROM AUTHOR]

Published

2018