| Literature DB >> 26871684 |
Liwen Hu1, Yang Song1, Shuqiang Jiao2, Yingjun Liu3, Jianbang Ge1, Handong Jiao1, Jun Zhu1, Junxiang Wang1, Hongmin Zhu1, Derek J Fray4.
Abstract
Producing graphene through the electrochemical reduction of CO2 remains a great challenge, which requires precise control of the reaction kinetics, such as diffusivities of multiple ions, solubility of various gases, and the nucleation/growth of carbon on a surface. Here, graphene was successfully created from the greenhouse gas CO2 using molten salts. The results showed that CO2 could be effectively fixed by oxygen ions in CaCl2-NaCl-CaO melts to form carbonate ions, and subsequently electrochemically split into graphene on a stainless steel cathode; O2 gas was produced at the RuO2-TiO2 inert anode. The formation of graphene in this manner can be ascribed to the catalysis of active Fe, Ni, and Cu atoms at the surface of the cathode and the microexplosion effect through evolution of CO in between graphite layers. This finding may lead to a new generation of proceedures for the synthesis of high value-added products from CO2, which may also contribute to the establishment of a low-carbon and sustainable world.Entities:
Keywords: carbon dioxide; electrochemistry; graphene; molten salt; reduction
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Year: 2016 PMID: 26871684 DOI: 10.1002/cssc.201501591
Source DB: PubMed Journal: ChemSusChem ISSN: 1864-5631 Impact factor: 8.928