A process for the preparation of reduced graphene comprising the steps of: providing an expandable graphite intercalated with oxygen containing groups; heating the expandable graphite under conditions sufficient to cause expansion of the expandable graphite and formation of an expanded graphite comprising oxygen containing groups; and contacting the expanded graphite with carbon monoxide to reduce at least a portion of the oxygen containing groups and form a reduced expanded graphite comprising an array of reduced graphene. The process of the invention enables large volumes of high quality graphene to be produced.

A process for the preparation of reduced graphene comprising the steps of: providing an expandable graphite intercalated with oxygen containing groups; heating the expandable graphite under conditions sufficient to cause expansion of the expandable graphite and formation of an expanded graphite comprising oxygen containing groups; and contacting the expanded graphite with carbon monoxide to reduce at least a portion of the oxygen containing groups and form a reduced expanded graphite comprising an array of reduced graphene. The process of the invention enables large volumes of high quality graphene to be produced.

This disclosure relates to a hydrophilic graphitic material. The graphitic material may be a carbon nanotube film having superior chemical, mechanical and electrical properties compared to traditional membrane materials. The hydrophilic graphitic material includes a kosmotropic polymer or kosmotropic molecule coating that increases the hydrophilicity of a graphitic material. Methods for preparing the hydrophilic graphitic material are disclosed along with potential applications and uses.

This disclosure relates to a hydrophilic graphitic material. The graphitic material may be a carbon nanotube film having superior chemical, mechanical and electrical properties compared to traditional membrane materials. The hydrophilic graphitic material includes a kosmotropic polymer or kosmotropic molecule coating that increases the hydrophilicity of a graphitic material. Methods for preparing the hydrophilic graphitic material are disclosed along with potential applications and uses.

Embodiments relating to the synthesis and processing of graphene molecules are provided. In some cases, methods for the electrochemical expansion and/or functionalization of graphene molecules are provided. In some embodiments, one or more species may be intercalated between adjacent graphene sheets.

Embodiments relating to the synthesis and processing of graphene molecules are provided. In some cases, methods for the electrochemical expansion and/or functionalization of graphene molecules are provided. In some embodiments, one or more species may be intercalated between adjacent graphene sheets.

Provided is a sulfur-carbon material composite body which, when used for an electrode of a secondary battery, is unlikely to degrade cycle characteristics at the time of charging and discharging of the secondary battery. Disclosed is a sulfur-carbon material composite body including a first carbon material having a graphene layered structure; a spacer at least partially disposed between graphene layers of the first carbon material or at an end of the first carbon material; and sulfur or a sulfur-containing compound at least partially disposed between the graphene layers of the first carbon material or at the end of the first carbon material.

There is described a carbon material comprising sp.sup.2 and sp.sup.3 hybridised carbon. Also described is a method of making a carbon material the method comprising: exposing a substrate to a flux of at least 10.sup.11 carbon ions per cm.sup.2 of substrate per 1 ms, a majority of the carbon ions having a kinetic energy of at least 10 eV. Further, electrodes comprising the carbon material are described. The electrodes may operate as an anode in Li ion battery characterised with improved specific capacity and operation life-time.

There is described a carbon material comprising sp.sup.2 and sp.sup.3 hybridised carbon. Also described is a method of making a carbon material the method comprising: exposing a substrate to a flux of at least 10.sup.11 carbon ions per cm.sup.2 of substrate per 1 ms, a majority of the carbon ions having a kinetic energy of at least 10 eV. Further, electrodes comprising the carbon material are described. The electrodes may operate as an anode in Li ion battery characterised with improved specific capacity and operation life-time.

A method for manufacturing an electroconductive film includes a liquid composition preparation step for preparing a liquid composition including an electroconductive agent, an elastomer, and a solvent, the electroconductive agent having thinned graphite in which layers of graphite are thinned and which has a bulk density of 0.05 g/cm3 or lower; a delamination treatment step for performing interlayer delamination of the thinned graphite by pressurizing the liquid composition and passing same through a nozzle; and a hardening step for coating a substrate with the delamination-treated liquid composition and hardening a coated film. According to the method, thinning of the graphite processes sufficiently and the thinning process can be performed in shorter time than conventionally possible, and makes it also possible to manufacture an electroconductive film that has high electroconductivity and has electrical resistance unlikely to increase even after repeated extension.