Single or few-layer graphene (FLG) sheets offer extraordinary electronic, thermal and mechanical properties and are expected to find a variety of applications. Fully exploiting the properties of graphene will require a method for the production of high-quality graphene sheets (almost pristine graphene) in large quantities. In this regard, we report a two-step method for obtaining a homogenous colloidal suspension of single or FLG sheets up to 0.15 mg ml(-1) in N,N-dimethylformamide solution. The graphene nanostructures are directly imaged using a high-resolution transmission electron microscope (HRTEM) operated at 200 kV with a point resolution of 0.16 nm. We observed rotational misorientation within the flake in the HRTEM images of 2, 4 and 6 layers of graphene sheets, giving rise to Moiré patterns. By filtering in the frequency domain using a Fourier transform, we reconstruct the graphene lattice of each sheet and determine the relative rotation between consecutive graphene layers up, to six separate sheets. Direct evidence is obtained for FLG sheets with packing that is different to the standard AB Bernal packing of bulk graphite. Furthermore, we observed periodic ripples in suspended graphene sheets in our TEM measurements. Electrostatic force microscopy was used to characterize the electric potential distribution on the surface of FLG sheets on SiO2/Si substrates in ambient conditions. The FLG sheets were found to exhibit a conducting nature with small potential variations on the surface.
This work describes a new hydrothermal one-step method for the simple and controllable synthesis of reduced GO/nickel nanocomposites. The switchable diode effect induced by large resistive switching behaviour shows a promising potential for graphene based embedded nanoelectronic applications.
Here we demonstrate a single step approach for the facile reduction of graphene oxide (GO) to hydrogenated reduced graphene oxide (HRGO) under ambient conditions.
Enhanced electron-field emission from nanodiamond ridge-structured emission arrays capped on micropatterned silicon pillars Microstructure and its effect on field electron emission of grain-size-controlled nanocrystalline diamond films High current density field emission from arrays of carbon nanotubes and diamond-clad Si tips
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