Carbon 2005, 43:1731–1742.CrossRef 27. Wang H, Yang Y, Liang Y, Robinson JT, Li Y, Jackson A, Cui Y, Dai H: Graphene-wrapped sulfur particles as a rechargeable lithium-sulfur battery cathode material with high EPZ-6438 mouse capacity and cycling stability. Nano Lett 2011,
11:2644–2647.CrossRef 28. Evers S, Nazar LF: Graphene-enveloped sulfur in a one pot reaction: a cathode with good coulombic efficiency and high practical sulfur content. Chem Commun 2012, 48:1233–1235.CrossRef Competing interests The authors declare that they have no competing interests. Authors’ contributions ESS synthesized GHCS and carried out most of the experimental works. MSK contributed to some experiments involving the characterization of GHCS. WIC analyzed the experimental results. SHO developed the concept and designed the
experiments. All authors read and approved the final manuscript.”
“Background Graphene nanoribbons are finite-width graphene sheets, which are the one of the famous examples of nanocarbon materials [1, 2]. The electronic properties of graphene nanoribbons strongly depend on the edge structures. Graphene nanoribbons with zigzag edges have the so-called flat bands at the Fermi level [1, 2]. The states corresponding the flat bands are localized at the zigzag edges, i.e., the namely edge states [1, 2]. In the honeycomb lattice, there are two inequivalent sites, A and B sublattices. For the formation of edge states, this sublattice structure plays decisive role [1, 2]. On the other hand, boron-carbon-nitiride (BCN) materials, such as BCN nanotubes and graphite-like BCN, were synthesized by many groups [3–7]. Selleckchem GSK2879552 Quite recently, BCN sheets with BN and graphene domains were synthesized by Ci et al. [8]. Furthermore, a controllability of domain shapes was reported [9]. Fabrication of BCN nanoribbons was expected [10–14]. Therefore, such systems attract considerable interest for application for future electric
and optoelectric materials. Graphite-like BC2N sheet is one of the example of BCN, which was synthesized using chemical vapor depositions of boron trichloride, BCl3, and acetronitrile, CH3CN [15, 16]. The stabilities and electronic properties of BC2N sheets were investigated by several authors [17–19]. The electronic and magnetic properties of nanoribbons made with BC2N sheets were Phospholipase D1 also investigated by several authors [20–24]. The magnetism in BC2N nanoribbons is predicted [20, 21, 23, 24]. Xu et al. reported the presence of linear dispersion when atoms are arranged as C-B-N-C in the transverse direction [22]. Previously, the authors reported that the flat bands appear in zigzag BC2N nanoribbons where the atoms are arranged as B-C-N-C along the zigzag lines using a tight binding (TB) model [24]. The TB Combretastatin A4 in vitro approximation is an efficient method to describe the electronic properties compared with the density functional theories (DFT).