Methane/nitrogen plasma-assisted synthesis of graphene and carbon nanotubes

Shavelkina, M. B.; Филимонова, Е. А.; Амиров, Р. Х.; Isakaev, É. Kh.

doi:10.1088/1361-6463/aacc3d

Cited by 22 publications

(8 citation statements)

References 33 publications

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“…Shavelkina et al. [ 124 ] directly fabricated graphene and CNTs doped with nitrogen using a CH 4 ‐N 2 direct current (DC) plasma at pressures of 100–700 Torr. The N content of the CNTs reached up to 8 at%, and the formed graphene flakes displayed high thermal stability.…”

Section: Effect Of Discharge Gas On Cbmsmentioning

confidence: 99%

Advance in Using Plasma Technology for Modification or Fabrication of Carbon‐Based Materials and Their Applications in Environmental, Material, and Energy Fields

Sun

Bao

et al. 2020

Adv Funct Materials

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Plasma technology is an eco‐friendly way to modify or fabricate carbon‐based materials (CBMs) due to plasmas’ distinctive abilities in tuning the surface physicochemical properties by implanting functional groups or incorporating heteroatoms into the surface without changing the bulk structure. However, the mechanisms of functional groups formation on the carbon surface are still not clearly explained because of the variety of different discharge conditions and the complexity of plasma chemistry. Consequently, this paper contains a comprehensive review of plasma‐treated carbon‐based materials and their applications in environmental, materials, and energy fields. Plasma‐treated CBMs used in these fields have been significantly enhanced in recent years because these related materials possess unique features after plasma treatment, such as higher adsorption capacity, enhanced wettability, improved electrocatalytic activity, etc. Meanwhile, this paper also summarizes possible reaction routes for the generation of functional groups on CBMs. The outlook for future research is summarized, with suggestions that plasma technology research and development shall attempt to achieve precise control of plasmas to synthesize or to modify CBMs at the atomic level.

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Section: Effect Of Discharge Gas On Cbmsmentioning

confidence: 99%

Advance in Using Plasma Technology for Modification or Fabrication of Carbon‐Based Materials and Their Applications in Environmental, Material, and Energy Fields

Sun

Bao

et al. 2020

Adv Funct Materials

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“…Thus, it has been experimentally shown that using the DC plasma torch to generate the helium/propane-butane plasma jet, a highly efficient system for the graphene To analyse kinetic processes initiated in the arc plasma torch in the helium/propane-butane mixture, an approach was used similar to that described and applied in our work [18]. To determine the mixture composition in different temperature ranges in the gap between the reactor nozzle and the material collection point, we used our RADICAL software package [28][29][30] and the extended scheme of chemical reactions involving 769 reactions between 123 components.…”

Section: Sample Characterisationmentioning

confidence: 99%

“…Previously, we have shown a possibility of the graphene synthesis using the DC plasma torch, at pressures of 100-710 Torr [18][19][20]. Varying the plasma-forming gases and the carbon sources (solid, liquid, and gaseous carboncontaining substances), the jet cooling process, and the product collecting system, graphene, hydrogen and nitrogen modified graphene, as well as carbon nanotubes were synthesised in the same reactor.…”

Section: Introductionmentioning

confidence: 99%

Effect of helium/propane–butane atmosphere on the synthesis of graphene in plasma jet system

Shavelkina¹,

Филимонова²,

Амиров³

2020

Plasma Sources Sci. Technol.

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An experimental and theoretical study was performed on helium/propane-butane plasma, which enabled assembly of advanced carbon nanostructures, such as multilayer graphene flakes. A plasma jet was created at pressures ranging from 350 to 710 Torr, and with direct current plasma torch powers from 28 to 35 kW at varying mass ratios of helium to propane-butane 1:7.5 to 1:5. Graphene production was confirmed by different analytical techniques. The non-catalytic synthesis in the plasma jet volume provided the graphene purity. As a result of numerical simulation, the kinetic mechanism of the formation of carbon phase precursors in the gas phase, namely, C 2 dimers, was studied. The concentration of C 2 was determined, depending on the temperature and compared with the literature data on the pressure of saturated carbon vapours at temperatures ranging from 2500 to 5000 K. It is shown that the C 2 H-involving reactions provide additional C 2 production, leading to the formation of supersaturated vapour from C 2 molecules at temperatures of 2500 to 3500 K.

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“…Raman spectrum of graphane has specific peaks D, G and 2D at 1349, 1586 and 2695 nm with altered relation I D /I G (figure 5). According to [22][23][24] the relative intensity of the G-peak with respect to the 2D-peak (I G /I 2D ) along with the shape of the 2D-peak is also an indication of the number of graphene layers. The peculiarity of hydrogenated graphene synthesized by means of DC plasma torch in comparison with that in [4] is its origin in the volume of plasma jet, not as a result of the treatment of the pristine graphene with hydrogen containing medium.…”

Section: Samples Characterizationmentioning

confidence: 99%

1D modeling of the equilibrium plasma flow in the scope of direct current plasma torch assisted graphene synthesis

Shavelkina

Иванов

Bocharov

et al. 2019

J. Phys. D: Appl. Phys.

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Results of experimental study of the one-step plasma-based process of the synthesis of unsupported graphene and hydrogenated graphene are presented. A direct current (DC) plasma torch is used, the pressure is held at 350 Тоrr, and the flow rates of plasma forming gas (helium) and carbon source (propane-butane mixture) are kept constant. An influence of reactor geometry on the properties of synthesized product is investigated. Graphene and hydrogenated graphene were synthesized in an appreciable rate in the plasma jet volume under equal conditions using cylindrical and conical reactors accordingly. Synthesized graphene materials are characterized using electron microscopy, Raman spectroscopy, x-ray, and XPS analysis, confirming the existence of graphene and of hydrogenated graphene (graphane). In order to examine an influence of input parameters on the process of the synthesis of graphene materials, the quasi-1D numerical flow model is used to calculate the distributions of temperature and velocity within the reactor channel. The key role of the temperature distribution within the reactor in the synthesis of graphene materials is established. Cylindrical flow channel provides higher temperatures compared with the conical channel. It affects the flow composition at the outlet. Under lower temperature, the flow contains in addition to condensed carbon a great amount of hydrocarbons CH, which is favorable for the production of hydrogenated graphene. Under higher temperature, the pure graphene is synthesized, since the outlet flow has the carbon mainly in the condense phase, the quantity of CH being insignificant.

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Methane/nitrogen plasma-assisted synthesis of graphene and carbon nanotubes

Cited by 22 publications

References 33 publications

Advance in Using Plasma Technology for Modification or Fabrication of Carbon‐Based Materials and Their Applications in Environmental, Material, and Energy Fields

Advance in Using Plasma Technology for Modification or Fabrication of Carbon‐Based Materials and Their Applications in Environmental, Material, and Energy Fields

Effect of helium/propane–butane atmosphere on the synthesis of graphene in plasma jet system

1D modeling of the equilibrium plasma flow in the scope of direct current plasma torch assisted graphene synthesis

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