The invention relates to a method for producing a functionalised semiconductor or conductor material from a layered structured base material by electrolytic exfoliation in an electrolysis cell, comprising at least one electrode pair consisting of first and second electrodes, and an aqueous and/or alcoholic electrolyte solution, containing sulphuric acid and/or at least one salt selected from sulphate and/or hydrogen sulphate and/or perchlorate and/or persulphate salt, comprising the steps of: a) bringing the electrodes into contact with the electrolyte solution; b) electronically exfoliating the base material by applying a voltage between the first and the second electrode; c) separating the functionalised conductor or semiconductor material from the electrolyte solution, wherein at least the first of the electrodes of the electrode pair contains the layered, carbon-based base material, the first electrode being connected as an anode, wherein at least one organic compound is added to the electrolyte solution before and/or during and/or immediately after the electrolytic exfoliation, wherein the organic compound is selected from i) anodically oxidisable organic molecules containing at least one alcohol group and/or at least one amino group and/or at least one carboxyl group, and/or ii) organic molecules containing at least one isocyanate group and/or at least one halide group and/or at least one epoxide group and/or at least one diazonium group and/or at least one peroxide group and/or at least one azide group and/or cyclic esters and/or cyclic amides, and/or iii) precursors or monomers of electrically conductive polymers, and/or iv) free-radical polymerisable, water-soluble vinyl monomers which have in their structure at least one amino group and/or at least one anionic functional group.

A composition comprising reduced graphene oxide in the form of sheets that are interconnected to define pores between the sheets.

An improved nanocomposite cathode material for lithium-ion batteries and method of making the same. The nanocomposite cathode material includes lithium iron silicate based nanoparticles with a conductive matrix of graphene sheets. The nanoparticles may be doped with at least one anion or cation.

A coating process is described that coats a coil-to-coil continuous substrate with a graphene-like coating. The coating process includes cleaning and activating a substrate, applying a graphene oxide dispersion to the substrate, drying the coated sub-strate, and exposing the dried coating to VUV radiation under a dry atmosphere. The atmosphere for the last step includes one or more inert gases and optionally one or more reactive gases to repair defects in the coating and/or to functionalize the coating. This coating process allows for the formation of a polygranular graphene-like coating intimately in contact with the substrate. The graphene-like coating coats the substrate with multiple monolayers of graphene in a continuous manner.

Provided herein are graphene biosensors and related core particles, compositions methods and systems in which more than one pristine graphene sheet is coated with a coating layer of an organic or inorganic material to provide a core graphene particle, to which detectable components comprising a detectable moiety and a peptide linkage are attached through binding of the peptide linkage.

The present invention provides a method for forming a graphene film through horizontally tiling and self-assembling graphene, including: proportionally adding toluene and alcohol into a graphene aqueous solution to be fully and uniformly mixed; then pouring the mixture into a vacuum filtration device, wherein when a solution in a filter flask forms a layered solution system with upper and lower layers, graphene is confined at an interface and tiled horizontally under a shear force at the interface to allow (002) planes of graphene to gradually become parallel to the interface, and graphene to be self-assembled to form the graphene film; and activating the suction filtration device to remove the solution, to obtain a graphene film with the (002) planes parallel to each other at a microscopic level on a filter paper.

Graphenic carbon nanoparticles that are dispersed in solvents through the use of dispersant resins are disclosed. The graphenic carbon nanoparticles may be milled prior to dispersion. The dispersant resins may comprise a polymeric dispersant resin comprising an addition polymer comprising the residue of a vinyl heterocyclic amide, an addition polymer comprising a homopolymer, a block (co)polymer, a random (co)polymer, an alternating (co)polymer, a graft (co)polymer, a brush (co)polymer, a star (co)polymer, a telechelic (co)polymer, or a combination thereof. The solvents may be aqueous, non-aqueous, inorganic and/or organic solvents. The dispersions are highly stable and may contain relatively high loadings of the graphenic carbon nanoparticles.

A method of producing high conductivity carbon material from coal includes subjecting the coal to a dissolution process to produce a solubilized coal material, and subjecting the solubilized coal material to a pyrolysis process to produce the high conductivity carbon material.

Newly discovered allotrope of carbon having a multilayered nanocarbon array exhibits among other properties exceptional stability, electrical conductivity and electromagnetic frequency (emf) attenuation characteristics. Members of this new allotrope include nanocarbon structures possessing vast electron delocalization in multiple directions unavailable to known fullerene-characterized materials like carbon nano-onions (CNOs), multiwalled carbon nano-tubes (MWNTs), graphene, carbon nano-horns, and carbon nano-ellipsoids such that stabilizing electron delocalization crosses or proceeds between layers as well as along layers in multiple directions within a continuous cyclic structure having an advanced interlayer connectivity bonding system involving the whole carbon array apart from incidental defects.

The present development is a novel graphene foam with highly enriched incommensurately-stacked layers. The graphene foam is intended to be applied as active electrodes in rechargeable batteries. A 93% incommensurate graphene foam demonstrated a reversible specific capacity of 1540 mAh g.sup.-1 with a 75% coulombic efficiency, and an 86% incommensurate sample achieves above 99% coulombic efficiency exhibiting 930 mAh g.sup.-1 specific capacity.