Development of graphene layers by reduction of graphite fluoride C<sub>2</sub>F surface

Окотруб, А. В.; Asanov, I. P.; Yudanov, N. F.; Babin, K. S.; Гусельников, А. В.; Nedoseikina, T. I.; Гевко, П. Н.; Bulusheva, L. G.; Osváth, Z.; Biró, L. P.

doi:10.1002/pssb.200982296

Cited by 25 publications

(19 citation statements)

References 17 publications

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“…F-FLG nanosheets are composed of 3-4 layers (considering an interlayer separation of about 0.6 nm) with some thicker areas, which are presumably caused by wrinkling. [38] Our preliminary experiments showed that F-FLG reacted vigorously with hydrazine and instantly blackened and swelled upon interaction with ethylenediamine and butylamine, presumably forming a kind of pillared structures, similar to what was observed for graphene oxide. The dispersions in tert-butanol were stable in the liquid state for up to 1 week, which is enough for prospective processing steps.…”

Section: Dispersion Of Few-layer Fluorinated Graphene C 2 Fsupporting

confidence: 62%

Synthesis, Properties, and Dispersion of Few‐Layer Graphene Fluoride

Grayfer

Makotchenko

Kibis

et al. 2013

Chemistry An Asian Journal

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We have fluorinated few-layer graphene (FLG) by using a low-temperature fluorination route with gaseous ClF3. The treatment process resulted in a new graphene derivative with a finite approximate composition of C2F. TEM studies showed that the product consisted of thin transparent sheets with no more than 10 fluorographene layers stacked together. Spectroscopic methods revealed a predominantly covalent nature of the C-F bonds in the as-synthesized product and we found no evidence for the existence of so-called "semi-ionic" C-F bonds, as observed in bulk C(x)F. In contrast to the case of graphite and typical (thick) expanded graphites, fluorination of FLG did not lead to the intercalation of ClF3 molecules, owing to the lack of a 3D layered structure. The approximate "critical" number of graphene layers that were necessary to form a phase of intercalated compound was estimated to be more than 12, thus providing a "chemical proof" of the difference between the properties of few-layered graphenes and bulk graphites. Fluorographene C2F was successfully delaminated into thinner layers in organic solvents, which is an important property for its integration into electronic devices, nanohybrids, etc.

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Section: Dispersion Of Few-layer Fluorinated Graphene C 2 Fsupporting

confidence: 62%

Synthesis, Properties, and Dispersion of Few‐Layer Graphene Fluoride

Grayfer

Makotchenko

Kibis

et al. 2013

Chemistry An Asian Journal

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“…chemical and/or thermal reduction of graphite derivatives such as graphite oxide (GO) 60 and graphite fluoride 61 appears to be the most suitable and efficient strategy (cf. Fig.…”

Section: Figmentioning

confidence: 99%

Graphene based metal and metal oxide nanocomposites: synthesis, properties and their applications

et al. 2015

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“…We perform first-principles density functional calculations in the dense and dilute limits of fluorine coverage, to quantify the spin-orbit splitting of the relevant energy bands. Our dense limit is given by the single-side semifluorinated graphene (C 2 F) which can be experimentally prepared by the chemical reduction of oxidized graphite surfaces [26]. Our study focuses on the chair conformation of C 2 F which is metallic within DFT, as well as within GW calculations [27].…”

Section: Introductionmentioning

confidence: 99%

Spin-orbit coupling in fluorinated graphene

et al. 2015

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We report on theoretical investigations of the spin-orbit coupling effects in fluorinated graphene. First-principles density functional calculations are performed for the dense and dilute adatom coverage limits. The dense limit is represented by the single-side semifluorinated graphene, which is a metal with spin-orbit splittings of about 10 meV. To simulate the effects of a single adatom, we also calculate the electronic structure of a 10 × 10 supercell, with one fluorine atom in the top position. Since this dilute limit is useful to study spin transport and spin relaxation, we also introduce a realistic effective hopping Hamiltonian, based on symmetry considerations, which describes the supercell bands around the Fermi level. We provide the Hamiltonian parameters which are best fits to the first-principles data. We demonstrate that, unlike for the case of hydrogen adatoms, fluorine's own spin-orbit coupling is the principal cause of the giant induced local spin-orbit coupling in graphene. The sp 3 hybridization induced transfer of spin-orbit coupling from graphene's σ bonds, important for hydrogenated graphene, contributes much less. Furthermore, the magnitude of the induced spin-orbit coupling due to fluorine adatoms is about 1000 times more than that of pristine graphene, and 10 times more than that of hydrogenated graphene. Also unlike hydrogen, the fluorine adatom is not a narrow resonant scatterer at the Dirac point. The resonant peak in the density of states of fluorinated graphene in the dilute limit lies 260 meV below the Dirac point. The peak is rather broad, about 300 meV, making the fluorine adatom only a weakly resonant scatterer.

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Development of graphene layers by reduction of graphite fluoride C₂F surface

Cited by 25 publications

References 17 publications

Synthesis, Properties, and Dispersion of Few‐Layer Graphene Fluoride

Synthesis, Properties, and Dispersion of Few‐Layer Graphene Fluoride

Graphene based metal and metal oxide nanocomposites: synthesis, properties and their applications

Spin-orbit coupling in fluorinated graphene

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Development of graphene layers by reduction of graphite fluoride C2F surface

Cited by 25 publications

References 17 publications

Synthesis, Properties, and Dispersion of Few‐Layer Graphene Fluoride

Synthesis, Properties, and Dispersion of Few‐Layer Graphene Fluoride

Graphene based metal and metal oxide nanocomposites: synthesis, properties and their applications

Spin-orbit coupling in fluorinated graphene

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Product

Resources

About

Development of graphene layers by reduction of graphite fluoride C₂F surface