Abstract: A water resistant sealing material suitable as a gasket or valve seal is described. The sealing material comprises modified chemically exfoliated vermiculite (CEV) in a proportion of 30-70% w/w sealing material and a filler in a proportion of 70-30% w/w sealing material, and optionally other additives in a proportion of 0-10% w/w sealing material. The modified CEV comprises water resistance enhancing monovalent cations. The sealing material is particularly useful to provide improved water resistance in gaskets and valve seals.

Abstract: The present invention provides a method for producing a solution of nanosheets, comprising the step of contacting an intercalated layered material with a polar aprotic solvent to produce a solution of nanosheets, wherein the intercalated layered material is prepared from a layered material selected from the group consisting of a transition metal dichalcogenide, a transition metal monochalcogenide, a transition metal trichalcogenide, a transition metal oxide, a metal halide, an oxychalcogenide, an oxypnictide, an oxyhalide of a transition metal, a trioxide, a perovskite, a niobate, a ruthenate, a layered III-VI semiconductor, black phosphorous and a V-VI layered compound. The invention also provides a solution of nanosheets and a plated material formed from nanosheets.

Abstract: A water resistant sealing material suitable as a gasket or valve seal is described. The sealing material comprises modified chemically exfoliated vermiculite (CEV) in a proportion of 30-70% w/w sealing material and a filler in a proportion of 70-30% w/w sealing material, and optionally other additives in a proportion of 0-10% w/w sealing material. The modified CEV comprises water resistance enhancing monovalent cations. The sealing material is particularly useful to provide improved water resistance in gaskets and valve seals.

Abstract: The present invention provides a method for producing a solution of nanosheets, comprising the step of contacting an intercalated layered material with a polar aprotic solvent to produce a solution of nanosheets, wherein the intercalated layered material is prepared from a layered material selected from the group consisting of a transition metal dichalcogenide, a transition metal monochalcogenide, a transition metal trichalcogenide, a transition metal oxide, a metal halide, an oxychalcogenide, an oxypnictide, an oxyhalide of a transition metal, a trioxide, a perovskite, a niobate, a ruthenate, a layered III-VI semiconductor, black phosphorous and a V-VI layered compound. The invention also provides a solution of nanosheets and a plated material formed from nanosheets.

Abstract: A method for dispersing nanotubes, comprising contacting the nanotubes with an electronic liquid comprising a metal and an amine solvent, a solution of dispersed nanotubes, comprising individual nanotubes at a concentration of greater than about 0.01 mgml?1 and a solvent and a nanotube crystal comprising a close packed array of nanotubes, wherein the crystal has a thickness of 100 nm or more are described.

Abstract: A method for producing a solution of dispersed graphenes comprising contacting graphite having a dimension in the a-b plane of 10 ?m or less with an electronic liquid comprising a metal and a polar aprotic solvent, and solutions of dispersed graphenes which may be obtained by such a method are described.

Abstract: A method for dispersing nanomaterial comprising an electrochemical process, a solution of dispersed nanomaterial, comprising individual charged nanomaterial at a concentration of about 0.1 mgm?1 or more and a solvent and an electrochemical cell are described.

Abstract: A method for producing a solution of dispersed graphenes comprising contacting graphite having a dimension in the a-b plane of 10 ?m or less with an electronic liquid comprising a metal and a polar aprotic solvent, and solutions of dispersed graphenes which may be obtained by such a method are described.

Abstract: A method for removing impurities from a sample of carbon nanotubes wherein the sample is contacted with an electronic liquid comprising a metal and an amine solvent is described.

Abstract: A method for dispersing carbon nanotubes, wherein the nanotubes are contacted with an electronic liquid wherein the ratio to metal atoms in the electronic liquid to carbon atoms in the carbon nanotubes is controlled and a solution of carbon nanotubes obtainable by such a method is described.

Abstract: A method for dispersing nanomaterial comprising an electrochemical process, a solution of dispersed nanomaterial, comprising individual charged nanomaterial at a concentration of about O.1 mgm?1 or more and a solvent and an electrochemical cell are described.