Comparative electron paramagnetic resonance investigation of reduced graphene oxide and carbon nanotubes with different chemical functionalities for quantum dot attachment

Pham, Chuyen Van; Krueger, Michael; Eck, Michael J.; Weber, Stefan; Erdem, Emre

doi:10.1063/1.4870297

Cited by 85 publications

(59 citation statements)

References 35 publications

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“…This line corresponded to g ¼ 2.0027 and originated from a SiC substrate. 18 We were not able to detect any carbon like ESR signal that has been reported for functionalized graphene oxide [19][20][21] and could be related to graphene layer. In case of the NaCl-treated graphene, several additional lines were observed for magnetic field in the range between 0.31 T and 0.38 T. 22 These lines were very well visible for magnetic field perpendicular to the sample surface however, with deviation of an angle from perpendicular orientation, a rapid decrease in their amplitude was observed.…”

Section: Resultscontrasting

confidence: 60%

Electron scattering in graphene with adsorbed NaCl nanoparticles

Drabińska

Kaźmierczak

Bożek

et al. 2015

Journal of Applied Physics

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In this work, the results of contactless magnetoconductance and Raman spectroscopy measurements performed for a graphene sample after its immersion in NaCl solution were presented. The properties of the immersed sample were compared with those of a non-immersed reference sample. Atomic force microscopy and electron spin resonance experiments confirmed the deposition of NaCl nanoparticles on the graphene surface. A weak localization signal observed using contactless magnetoconductance showed the reduction of the coherence length after NaCl treatment of graphene. Temperature dependence of the coherence length indicated a change from ballistic to diffusive regime in electron transport after NaCl treatment. The main inelastic scattering process was of the electron-electron type but the major reason for the reduction of the coherence length at low temperatures was additional, temperature independent, inelastic scattering. We associate it with spin flip scattering, caused by NaCl nanoparticles present on the graphene surface. Raman spectroscopy showed an increase in the D and D′ bands intensities for graphene after its immersion in NaCl solution. An analysis of the D, D′, and G bands intensities proved that this additional scattering is related to the decoration of vacancies and grain boundaries with NaCl nanoparticles, as well as generation of new on-site defects as a result of the decoration of the graphene surface with NaCl nanoparticles. The observed energy shifts of 2D and G bands indicated that NaCl deposition on the graphene surface did not change carrier concentration, but reduced compressive biaxial strain in the graphene layer.

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Section: Resultscontrasting

confidence: 60%

Electron scattering in graphene with adsorbed NaCl nanoparticles

Drabińska

Kaźmierczak

Bożek

et al. 2015

Journal of Applied Physics

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“…This result indicates an increment of moieties in the nGO structure which would be responsible for the increase in signal. Other researchers have proposed that these moieties would correspond to the oxidized groups such as -OH and -COOH produced during the oxidation of graphite [28]. In the case of bulk graphite the ESR line is Dysonian due to the skin effect, characteristic of conductive materials, whereas the nGO spectrum presents a single Lorentzian curve suggesting a loss of conductivity which represents another evidence of the introduction of defects in graphite structure due to oxidation [29].…”

Section: Ngo and Chi:ngo Characterizationmentioning

confidence: 97%

Development of a chitin/graphene oxide hybrid composite for the removal of pollutant dyes: Adsorption and desorption study

González

Villanueva

Piehl

et al. 2015

Chemical Engineering Journal

197

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“…Other reported in the literature method of obtaining GO without Mn contamination is done by the use of different oxidizing agents, e.g. HNO 3 /H 2 SO 4 instead of KMnO 4 [64]. Reference (pristine) prGO aerogel presents a weak EPR signal which consists of two components with similar g factors (g = 2.00), but one has the linewidth of 0.38 mT and small intensity, and the second 9.2 mT and much stronger intensity.…”

Section: Epr Spectroscopy Of Tmi-doped Prgo Aerogelsmentioning

confidence: 99%

Preparation and characterization of partially reduced graphene oxide aerogels doped with transition metal ions

et al. 2018

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This work presents the preparation and characterization of pristine and transition metal doped partially reduced graphene oxide aerogels. The step-by-step preparation of aerogels from graphene oxide with an assistance of VCl 3 , CrCl 3 , FeCl 2 Á4H 2 O, CoCl 2 , NiCl 2 and CuCl 2 chlorides as reducing agents is shown and explained. The influence of reducing agents on the structural and magnetic properties of prepared aerogels is investigated. The use of electron paramagnetic resonance in purification during synthesis of GO and characterization afterwards is shown. It was found that VCl 3 was the strongest reducing agent leading to the formation of the most dense reduced graphene oxide aerogel, whereas vanadium is visible in EPR spectrum in form of V 4? complex as a VO 2?groups.

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Comparative electron paramagnetic resonance investigation of reduced graphene oxide and carbon nanotubes with different chemical functionalities for quantum dot attachment

Cited by 85 publications

References 35 publications

Electron scattering in graphene with adsorbed NaCl nanoparticles

Electron scattering in graphene with adsorbed NaCl nanoparticles

Development of a chitin/graphene oxide hybrid composite for the removal of pollutant dyes: Adsorption and desorption study

Preparation and characterization of partially reduced graphene oxide aerogels doped with transition metal ions

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