An Exceptionally Efficient Co−Co2P@N, P‐Codoped Carbon Hybrid Catalyst for Visible Light‐Driven CO2‐to‐CO Conversion

Artificial photosynthesis has attracted wide attention, particularly the development of efficient solar light‐driven methods to reduce CO2 to form energy‐rich carbon‐based products. Because CO2 reduction is an uphill process with a large energy barrier, suitable catalysts are necessary to achieve th...

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Veröffentlicht in:	Chemistry : a European journal 2018-06, Vol.24 (34), p.8596-8602
Hauptverfasser:	Xu, Yong, Mo, Jiang, Fu, Zi‐Cheng, Liu, Su, Yang, Zhi, Fu, Wen‐Fu
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Sprache:	eng
Schlagworte:	Carbon Carbon dioxide Carbon monoxide Catalysis Catalysts Chemical synthesis Chemistry CO2 reduction cobalt Conversion Genetic transformation Hybrid systems Molecular chains Morphology N, P-codoped carbon Nanoparticles photocatalysis Photochemistry Photoreduction Photosynthesis Reduction ruthenium Water chemistry
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creator	Xu, Yong Mo, Jiang Fu, Zi‐Cheng Liu, Su Yang, Zhi Fu, Wen‐Fu
description	Artificial photosynthesis has attracted wide attention, particularly the development of efficient solar light‐driven methods to reduce CO2 to form energy‐rich carbon‐based products. Because CO2 reduction is an uphill process with a large energy barrier, suitable catalysts are necessary to achieve this transformation. In addition, CO2 adsorption on a catalyst and proton transfer to CO2 are two important factors for the conversion reaction, and catalysts with high surface area and more active sites are required to improve the efficiency of CO2 reduction. Here, a visible light‐driven system for CO2‐to‐CO conversion is reported, which consists of a heterogeneous hybrid catalyst of Co and Co2P nanoparticles embedded in carbon nanolayers codoped with N and P (Co‐Co2P@NPC) and a homogeneous RuII‐based complex photosensitizer. The average generation rate of CO of the system was up to 35 000 μmol h−1 g−1 with selectivity of 79.1 % in 3 h. Linear CO production at an exceptionally high rate of 63 000 μmol h−1 g−1 was observed in the first hour of reaction. Inspired by this highly active catalyst, Co@NC and Co2P@NPC materials were also synthesized and their structure, morphology, and catalytic properties for CO2 photoreduction were explored. The results showed that the nanoparticle size, partially adsorbed H2O molecules on the catalyst surface, and the hybrid nature of the systems influenced their photocatalytic CO2 reduction performance. A hybrid photocatalyst consisting of Co and Co2P nanoparticles embedded in N, P‐codoped carbon nanosheets was used in a visible light‐driven system for CO2‐to‐CO conversion. The catalytic system displayed a high CO production rate of up to 35 000 μmol h−1 g−1 with CO selectivity of 79.1 % in the first 3 h of reaction. Linear CO production at an exceptionally high rate of 63 000 μmol h−1 g−1 was observed in the first 1 h of photocatalytic reaction.
doi_str_mv	10.1002/chem.201801465
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Because CO2 reduction is an uphill process with a large energy barrier, suitable catalysts are necessary to achieve this transformation. In addition, CO2 adsorption on a catalyst and proton transfer to CO2 are two important factors for the conversion reaction, and catalysts with high surface area and more active sites are required to improve the efficiency of CO2 reduction. Here, a visible light‐driven system for CO2‐to‐CO conversion is reported, which consists of a heterogeneous hybrid catalyst of Co and Co2P nanoparticles embedded in carbon nanolayers codoped with N and P (Co‐Co2P@NPC) and a homogeneous RuII‐based complex photosensitizer. The average generation rate of CO of the system was up to 35 000 μmol h−1 g−1 with selectivity of 79.1 % in 3 h. Linear CO production at an exceptionally high rate of 63 000 μmol h−1 g−1 was observed in the first hour of reaction. Inspired by this highly active catalyst, Co@NC and Co2P@NPC materials were also synthesized and their structure, morphology, and catalytic properties for CO2 photoreduction were explored. The results showed that the nanoparticle size, partially adsorbed H2O molecules on the catalyst surface, and the hybrid nature of the systems influenced their photocatalytic CO2 reduction performance. A hybrid photocatalyst consisting of Co and Co2P nanoparticles embedded in N, P‐codoped carbon nanosheets was used in a visible light‐driven system for CO2‐to‐CO conversion. The catalytic system displayed a high CO production rate of up to 35 000 μmol h−1 g−1 with CO selectivity of 79.1 % in the first 3 h of reaction. 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Inspired by this highly active catalyst, Co@NC and Co2P@NPC materials were also synthesized and their structure, morphology, and catalytic properties for CO2 photoreduction were explored. The results showed that the nanoparticle size, partially adsorbed H2O molecules on the catalyst surface, and the hybrid nature of the systems influenced their photocatalytic CO2 reduction performance. A hybrid photocatalyst consisting of Co and Co2P nanoparticles embedded in N, P‐codoped carbon nanosheets was used in a visible light‐driven system for CO2‐to‐CO conversion. The catalytic system displayed a high CO production rate of up to 35 000 μmol h−1 g−1 with CO selectivity of 79.1 % in the first 3 h of reaction. 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Inspired by this highly active catalyst, Co@NC and Co2P@NPC materials were also synthesized and their structure, morphology, and catalytic properties for CO2 photoreduction were explored. The results showed that the nanoparticle size, partially adsorbed H2O molecules on the catalyst surface, and the hybrid nature of the systems influenced their photocatalytic CO2 reduction performance. A hybrid photocatalyst consisting of Co and Co2P nanoparticles embedded in N, P‐codoped carbon nanosheets was used in a visible light‐driven system for CO2‐to‐CO conversion. The catalytic system displayed a high CO production rate of up to 35 000 μmol h−1 g−1 with CO selectivity of 79.1 % in the first 3 h of reaction. 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subjects	Carbon Carbon dioxide Carbon monoxide Catalysis Catalysts Chemical synthesis Chemistry CO2 reduction cobalt Conversion Genetic transformation Hybrid systems Molecular chains Morphology N, P-codoped carbon Nanoparticles photocatalysis Photochemistry Photoreduction Photosynthesis Reduction ruthenium Water chemistry
title	An Exceptionally Efficient Co−Co2P@N, P‐Codoped Carbon Hybrid Catalyst for Visible Light‐Driven CO2‐to‐CO Conversion
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