Modulating carbon growth kinetics enables electrosynthesis of graphite derived from CO2 via a liquid–solid–solid process

Modulating carbon growth kinetics enables electrosynthesis of graphite derived from CO2 via a liquid–solid–solid process

Highly graphitic carbon materials have gained considerable interests in practical applications, however, an efficient and cost-effective synthesis strategy using low-grade carbonaceous precursors is still in urgent need. In this work, we successfully synthesize well-crystalline graphite derived from...

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Bibliographic Details
Published in:Carbon (New York) Vol. 184; pp. 426 - 436
Main Authors: Yu, Rui, Deng, Bowen, Du, Kaifa, Chen, Di, Gao, Muxing, Wang, Dihua
Format: Journal Article
Language:English
Published: New York Elsevier Ltd 30-10-2021
Elsevier BV
Subjects:
Carbon
Carbon dioxide
Carbon fibers
Cathodes
Cathodic dissolution
CO2 conversion
Crystal structure
Crystallinity
Current density
Dissolution
Electrolysis
Graphene
Graphite
Growth kinetics
High temperature
Molten salt
Molten salts
Nanotubes
Nickel
Operating temperature
Studies
Substrates
Transition metals
Electrolysis
CO2 conversion
Graphene
Growth kinetics
Molten salt
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Summary:Highly graphitic carbon materials have gained considerable interests in practical applications, however, an efficient and cost-effective synthesis strategy using low-grade carbonaceous precursors is still in urgent need. In this work, we successfully synthesize well-crystalline graphite derived from CO2 by molten carbonate electrolysis under a mild operating temperature, where the as-formed carbon atoms follow a “dissolution–precipitation” process on a Ni cathode. Attributed to that Ni cathode can in situ act as a solid solvent for periodically accommodating/dissolving the as-formed carbon atoms, deliberately coordinating carbon formation flux with carbon dissolution flux can lead to the consecutive production of highly crystalline graphite, without contamination of transition metal catalyst. It was found that a low carbon deposition current density and a relatively high operating temperature (650–750 °C) both facilitate the growth of graphite structures, because a moderate current density enables a suitable carbon flux originating from the electro-reduction of the captured CO2 (in the form of CO32− in molten salts), which can more accessibly match the carbon dissolution flux in Ni substrate at an elevated temperature. The thickness of graphite can be easily controlled by electrolysis durations. This work provides a simple strategy to convert CO2 into graphitic carbon products with both promising purity and crystallinity. [Display omitted] •Electrosynthesis of graphite derived from CO2 is achieved.•A liquid–solid–solid process for graphite growth is first proposed.•Coordinating carbon formation flux with carbon dissolution flux enables graphite growth.•A low current density and a relatively high temperature both facilitate graphite growth.•The thickness of graphite can be regulated by electrolysis duration.
ISSN:0008-6223
1873-3891
DOI:10.1016/j.carbon.2021.08.033