Detail publikačního výsledku
On the Transition of Reaction Pathway during Microwave Plasma Gas-Phase Synthesis of Graphene Nanosheets: From Amorphous to Highly Crystalline Structure
TOMAN, J.; JAŠEK, O.; SNIRER, M.; PAVLIŇÁK, D.; NAVRÁTIL, Z.; JURMANOVÁ, J.; CHUDJÁK, S.; KRČMA, F.; KUDRLE, V. ; MICHALIČKA, J.
Originální název
On the Transition of Reaction Pathway during Microwave Plasma Gas-Phase Synthesis of Graphene Nanosheets: From Amorphous to Highly Crystalline Structure
Anglický název
On the Transition of Reaction Pathway during Microwave Plasma Gas-Phase Synthesis of Graphene Nanosheets: From Amorphous to Highly Crystalline Structure
Druh
Článek WoS
Originální abstrakt
Fourier-transform infrared spectroscopy and proton-transfer-reaction-mass spectrometry are used in a complementary way to study gas-phase processes during decomposition of ethanol in a microwave plasma torch. Decomposition products (C, C-2 and simple hydrocarbons) reassemble into higher hydrocarbons and graphene nuclei and further grow into graphene nanosheets (GNS). Depending on microwave power, ethanol flow rate and molecular gas admixture, the material structure changes from amorphous to crystalline. The presence of C2n + 1Hy species was found to be responsible for the formation of defects in the GNS structure. O-2 and H-2 admixtures change the gas temperature axial profile and consequently modify reaction pathways influencing growth and production rate of GNS. Determination of reaction pathway selectivity enables us to predict whether high-quality or defective GNS are produced.
Anglický abstrakt
Fourier-transform infrared spectroscopy and proton-transfer-reaction-mass spectrometry are used in a complementary way to study gas-phase processes during decomposition of ethanol in a microwave plasma torch. Decomposition products (C, C-2 and simple hydrocarbons) reassemble into higher hydrocarbons and graphene nuclei and further grow into graphene nanosheets (GNS). Depending on microwave power, ethanol flow rate and molecular gas admixture, the material structure changes from amorphous to crystalline. The presence of C2n + 1Hy species was found to be responsible for the formation of defects in the GNS structure. O-2 and H-2 admixtures change the gas temperature axial profile and consequently modify reaction pathways influencing growth and production rate of GNS. Determination of reaction pathway selectivity enables us to predict whether high-quality or defective GNS are produced.
Klíčová slova
: admixture, graphene nanosheets, microwave plasma, nucleation, plasma synthesis; hydrogen-production, ethanol decomposition, soot formation, inception growth kinetics
Klíčová slova v angličtině
: admixture, graphene nanosheets, microwave plasma, nucleation, plasma synthesis; hydrogen-production, ethanol decomposition, soot formation, inception growth kinetics
Autoři
TOMAN, J.; JAŠEK, O.; SNIRER, M.; PAVLIŇÁK, D.; NAVRÁTIL, Z.; JURMANOVÁ, J.; CHUDJÁK, S.; KRČMA, F.; KUDRLE, V. ; MICHALIČKA, J.
Rok RIV
2022
Vydáno
10.05.2021
ISSN
1612-8850
Periodikum
Plasma Processes and Polymers
Svazek
18
Číslo
8
Stát
Spolková republika Německo
Strany od
202100008
Strany do
202100008
Strany počet
22
URL
BibTex
@article{BUT172121,
author="TOMAN, J. and JAŠEK, O. and SNIRER, M. and PAVLIŇÁK, D. and NAVRÁTIL, Z. and JURMANOVÁ, J. and CHUDJÁK, S. and KRČMA, F. and KUDRLE, V. and MICHALIČKA, J.",
title="On the Transition of Reaction Pathway during Microwave Plasma Gas-Phase Synthesis of Graphene Nanosheets: From Amorphous to Highly Crystalline Structure",
journal="Plasma Processes and Polymers",
year="2021",
volume="18",
number="8",
pages="202100008--202100008",
doi="10.1002/ppap.202100008",
issn="1612-8850",
url="https://onlinelibrary.wiley.com/doi/epdf/10.1002/ppap.202100008?saml_referrer"
}Dokumenty