Nature of Graphene Edges: A Review

Açık, Müge; Chabal, Yves J.

doi:10.1143/jjap.50.070101

Cited by 157 publications

(106 citation statements)

References 168 publications

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“…5 Between the zigzag (z) and armchair-edged NRs, zigzagedged NRs are more interesting because of the presence of enhanced local-density of states near the Fermi-level, which in turn arise because of the localized electronic states at their edges. 6 Also, as proved by the previous studies on zGNRs 5,8,9 and zBNNRs, 3,10,11 these edge states can be tuned using different methods, namely, passivation, doping, substitution, application of external electric fields, and so on, to achieve tunable electronic and magnetic properties in these ribbons. Even, half-metallicity has been predicted in both zGNRs 7,8,12 and zBNNRs 1−3,13 under different conditions.…”

Section: Introductionmentioning

confidence: 80%

Electronic and Magnetic Properties of Zigzag Boron-Nitride Nanoribbons with Even and Odd-Line Stone-Wales (5–7 Pair) Defects

Yamijala

Pati

2013

J. Phys. Chem. C

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Spin-polarized first-principles calculations have been performed on zigzag boron−nitride nanoribbons (z-BNNRs) with lines of alternating fused pentagon (P) and heptagon (H) rings (pentagon−heptagon line defect) at a single edge as well as at both edges. The number of lines (n) of the pentagon−heptagon defect has been varied from 1 to 8 for 10-zBNNRs. Among the different spin-configurations that we have studied, we find that the spin-configuration with ferromagnetic ordering at each edge and antiferromagnetic ordering across the edges is quite interesting. For this spinconfiguration, we find that, if the introduced PH line defect is odd-numbered, the systems behave as spin-polarized semiconductors, but, for even-numbered, all the systems show interesting antiferromagnetic half-metallic behavior. Robustness of these results has been cross checked by the variation of the line-defect position and also by the variation of the width [from ∼1.1 nm (6-zBNNR) to ∼3.3 nm (16-zBNNR)] of the ribbon. Density of states (DOS), projected DOS, and band-structure analysis have been accomplished to understand the reasons for these differences between even and odd line defects. The main reason for many of the observed changes was traced back to the change in edge nature of the BNNR, which indeed dictates the properties of the systems.

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Section: Introductionmentioning

confidence: 80%

Electronic and Magnetic Properties of Zigzag Boron-Nitride Nanoribbons with Even and Odd-Line Stone-Wales (5–7 Pair) Defects

Yamijala

Pati

2013

J. Phys. Chem. C

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“…Therefore, it is critically important that these characteristics be accurately determined and controlled [10]. The surface chemistry of sp 2 carbon materials is governed by basal and edge carbon atoms [11,12], as well as by the presence of defects (i.e., structural carbon vacancies, non-aromatic rings) [13]. These imperfections and defects along the edges of graphene layers are the most active sites owing to high densities of unpaired electrons.…”

Section: The Surface Chemistry Of Carbon Materialsmentioning

confidence: 99%

“…Clusters with C 60 ligand. The first cluster coordinated to fullerene, [Ru 3 (CO) 9 ( 3 -2 , 2 , 2 -C 60 )], was synthesized in 1996 by thermal decarbonylation of [Ru 3 (CO) 12 ] in the presence of C 60 [507]. The X-ray diffraction shows that Ru atoms are 2 coordinated and positioned over the short C C bonds, the Ru C distances are in between 2.324(9) and 2.213(9)Å (Fig.…”

Section: Phmentioning

confidence: 99%

Coordination chemistry on carbon surfaces

Axet¹,

Dechy‐Cabaret²,

Durand³

et al. 2016

Coordination Chemistry Reviews

100

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“…The preferential oxidation might be due to that the edges had a higher chemical reactivity than the surfaces because the edges brought unpaired electrons [26]. Accordingly, low KMnO 4 additions would only produce a few of graphene oxide, for example GO-1 and GO-2 in Fig.…”

Section: Resultsmentioning

confidence: 99%