Synthesis of graphene-like carbon from agricultural side stream with magnesiothermic reduction coupled with atmospheric pressure induction annealing

Generally, large-scale production of graphene is currently not commercially viable due to expensive raw materials, complexity and the high-energy consumption of the processes currently used in the production. The use of biomass precursors and energy efficient procedures for carbonization have been p...

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Published inNano express Vol. 1; no. 1; pp. 10014 - 10022
Main Authors Lähde, Anna, Haluska, Ondrej, Alatalo, Sara-Maaria, Sippula, Olli, Meš eriakovas, Ar nas, Lappalainen, Reijo, Nissinen, Tuomo, Riikonen, Joakim, Lehto, Vesa-Pekka
Format Journal Article
LanguageEnglish
Published Bristol IOP Publishing 01.06.2020
Subjects
agricultural side stream
Annealing
Atmospheric pressure
biomass
Biomass energy production
Carbon
Energy consumption
Graphene
Graphitization
High temperature
induction annealing
magnesiothermic reduction
Phase separation
pyrolysis
Raman spectroscopy
Raw materials
Silicon carbide
Spectrum analysis
Synthesis
Thermogravimetry
Vaporization
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Summary:Generally, large-scale production of graphene is currently not commercially viable due to expensive raw materials, complexity and the high-energy consumption of the processes currently used in the production. The use of biomass precursors and energy efficient procedures for carbonization have been proposed to reduce the cost of the graphene materials. However, low-cost graphene production has not been accomplished yet. Herein, we present a sustainable procedure and renewable starting materials to synthesize carbon nanostructures with graphene-like features. First, a SiC/C composite was synthesized from phytoliths and sucrose through magnesiothermic reduction. The phytoliths were obtained from barley husk that is an abundant side stream of agricultural industry. Second, graphene-like structures were achieved by the graphitization of SiC/C composite with high temperature induction annealing at 2400 °C under atmospheric pressure. The formation of graphene-like carbon was initiated by vaporization of silicon from the pre-ceramic SiC/C. Complete transformation of SiC/C to hollow, spherical graphene-like carbon structures and sheets were verified with thermogravimetry, x-ray diffraction, energy dispersive spectroscopy, electron microscopy and Raman spectroscopy. Also, the theoretical thermodynamic consideration of the phase separation of silicon carbide and the role of free carbon in the process has been discussed.
Bibliography:NANOX-100057.R1
ISSN:2632-959X
2632-959X
DOI:10.1088/2632-959X/ab82e5