The invention provides liquid compositions comprising conductive carbon particles and/or carbon nanoparticles, a thickening agent, and a solvent. The carbon nanoparticles are preferably a mixture of graphite nanoplatelets and carbon nanotubes and the thickening agent is preferably a cellulose derivative. The liquid compositions can be used as ink to print highly conductive films that adhere to paper substrates.

A carbon nanostructure producing method includes a growth step in which a plurality of catalyst particles in close contact with each other are separated in a flow of a carbon-containing gas so as to grow carbon nanotubes between the plurality of catalyst particles, and an elongation step in which the carbon nanotube is elongated by a wind pressure of the carbon-containing gas with at least one of the catalyst particles being retained.

A carbon nanostructure producing method includes a growth step in which a plurality of catalyst particles in close contact with each other are separated in a flow of a carbon-containing gas so as to grow carbon nanotubes between the plurality of catalyst particles, and an elongation step in which the carbon nanotube is elongated by a wind pressure of the carbon-containing gas with at least one of the catalyst particles being retained.

The present disclosure relates to a carbon-based nanomaterial composition that may be formed from a gas mixture. The gas mixture may include acetylene gas at a molar ratio AG.sub.mol/GM.sub.mol of at least about 0.20 and not greater than about 0.99, oxygen gas at a molar ratio OG.sub.mol/GM.sub.mol of at least about 0.1 and not greater than about 0.85, and hydrogen gas at a molar ratio HG.sub.mol/GM.sub.mol of at least about 0.00 and not greater than about 0.99. The carbon-based nanomaterial composition may have a carbon hybridization ratio P.sub.sp3/P.sub.sp2 of not greater than about 5.0, where P.sub.sp3 is the percent of carbon within the carbon-based nanomaterial composition having a sp3 hybridization and P.sub.sp2 is the percent of carbon within the carbon-based nanomaterial composition having a sp2 hybridization.

The present disclosure relates to a carbon-based nanomaterial composition that may be formed from a gas mixture. The gas mixture may include acetylene gas at a molar ratio AG.sub.mol/GM.sub.mol of at least about 0.20 and not greater than about 0.99, oxygen gas at a molar ratio OG.sub.mol/GM.sub.mol of at least about 0.1 and not greater than about 0.85, and hydrogen gas at a molar ratio HG.sub.mol/GM.sub.mol of at least about 0.00 and not greater than about 0.99. The carbon-based nanomaterial composition may have a carbon hybridization ratio P.sub.sp3/P.sub.sp2 of not greater than about 5.0, where P.sub.sp3 is the percent of carbon within the carbon-based nanomaterial composition having a sp3 hybridization and P.sub.sp2 is the percent of carbon within the carbon-based nanomaterial composition having a sp2 hybridization.

The present disclosure relates to a patternable process for coating functional and adherent graphene-like carbon on multiple substrate types using CO.sub.2 laser-induced photothermal pyrolysis in scanning mode. The poly furfuryl alcohol (PFA) synthesised via low-temperature polymerisation of furfuryl alcohol precursor without any additives was used to form graphene-like carbon material.

The present disclosure relates to a patternable process for coating functional and adherent graphene-like carbon on multiple substrate types using CO.sub.2 laser-induced photothermal pyrolysis in scanning mode. The poly furfuryl alcohol (PFA) synthesised via low-temperature polymerisation of furfuryl alcohol precursor without any additives was used to form graphene-like carbon material.

Methods of producing graphene nanoplatelets by exposing graphite to a medium to form a dispersion of graphite in the medium. In some embodiments, the exposing results in formation of graphene nanoplatelets from the graphite. In some embodiments, the medium includes the following components: (a) an acid; (b) a dehydrating agent; and (c) an oxidizing agent. In some embodiments, the methods of the present disclosure result in the formation of graphene nanoplatelets at a yield of more than 90%. In some embodiments, the methods of the present disclosure result in the formation of graphene nanoplatelets in bulk quantities that are more than about a 1 kg of graphene nanoplatelets. Additional embodiments of the present disclosure pertains to the formed graphene nanoplatelets. In some embodiments, the graphene nanoplatelets include a plurality of layers, such as from about 1 layer to about 100 layers.

A low carbon footprint material is used to decrease the carbon dioxide emission for production of a high carbon footprint substance. A method of forming composite materials comprises providing a first high carbon footprint substance; providing a carbon nanomaterial produced with a carbon-footprint of less than 10 unit weight of carbon dioxide (CO.sub.2) emission during production of 1 unit weight of the carbon nanomaterial; and forming a composite comprising the high carbon footprint substance and from 0.001 wt % to 25 wt % of the carbon nanomaterial, wherein the carbon nanomaterial is homogeneously dispersed in the composite to reduce the carbon dioxide emission for producing the composite material relative to the high carbon footprint substance.

The present disclosure relates to methods for depositing vertically oriented carbon nanowalls (CNWs) using non-equilibrium gases such as gaseous plasma. Methods are disclosed for rapid deposition of uniformly distributed nanowalls on large surfaces of substrates using ablation of bulk carbon materials by reactive gaseous species, formation of oxidized carbon-containing gaseous molecules, ionization of said molecules and interacting said molecules, neutral or positively charged, with a substrate. The CNWs prepared are useful in different applications such as fuel cells, lithium ion batteries, photovoltaic devices and sensors of specific gaseous molecules.