Systems and methods are provided for fabrication of enhanced carbon fiber laminates that utilize encapsulated catalyst. One embodiment is a method that includes acquiring a batch of dry fibers, and acquiring a batch of catalyst capsules that each comprise catalyst that accelerates polymerization of monomers of a resin, and a shell that encapsulates the catalyst and liquefies at a curing temperature. The method further includes interspersing the catalyst capsules among the dry fibers, and impregnating the fibers with the resin after interspersing the catalyst capsules with the fibers.

Systems and methods are provided for fabrication of enhanced carbon fiber laminates that utilize encapsulated catalyst. One embodiment is a method that includes acquiring a batch of dry fibers, and acquiring a batch of catalyst capsules that each comprise catalyst that accelerates polymerization of monomers of a resin, and a shell that encapsulates the catalyst and liquefies at a curing temperature. The method further includes interspersing the catalyst capsules among the dry fibers, and impregnating the fibers with the resin after interspersing the catalyst capsules with the fibers.

A method and apparatus for manufacturing a carbon fiber. Pressure is applied to a filament to change a cross-sectional shape of the filament and create a plurality of distinct surfaces on the filament. The filament is converted into a graphitic carbon fiber having the plurality of distinct surfaces. A plurality of sizings is applied to the plurality of distinct surfaces of the graphitic carbon fiber in which the plurality of sizings includes at least two different sizings.

Carbon fiber and method of forming the same are provided. The method modifies proportion of a finishing oil to control a relation between a surface tension and a particle size of the finishing oil, and thus penetration of the finishing oil into an interior of the carbon fiber is avoided. Therefore, the carbon fiber can have both low oil residues and a high strength.

A method for processing a cotton-containing textile waste includes: separating cotton fibers from a batch of the textile waste; pretreating the cotton fibers by soaking in a hydroxide-ion-containing solution to obtain a mixture including pretreated carbon fibers; removing a liquid portion from the mixture to obtain the pretreated carbon fibers; subjecting the pretreated carbon fibers to enzymatic hydrolysis to form a sugary juice containing glucose; and e) adding the liquid portion as part of the hydroxide-ion-containing solution for pretreating the cotton fibers separated from a next batch of the textile waste.

A method of manufacturing a graphene fiber is provided. The method includes preparing a source solution including graphene oxide, supplying the source solution into a coagulation solution to form a graphene oxide fiber, reducing the graphene oxide fiber to form a primary graphene fiber, and Joule-heating the primary graphene fiber to form a secondary graphene fiber.

A method of manufacturing a graphene fiber is provided. The method includes preparing a source solution including graphene oxide, supplying the source solution into a coagulation solution to form a graphene oxide fiber, reducing the graphene oxide fiber to form a primary graphene fiber, and Joule-heating the primary graphene fiber to form a secondary graphene fiber.

Provided are: chopped carbon fiber bundles which have high fluidity without decreasing the dispersibility of carbon fibers and the physical properties of a molded product; and a method for producing chopped carbon fiber bundles with high productivity. Chopped carbon fiber bundles, each of which contain a carbon fiber bundle having a total fineness of from 25,000 dtex to 45,000 dtex (inclusive) and a sizing agent in an amount of from 1% by mass to 5% by mass (inclusive) relative to the total mass of the chopped carbon fiber bundle. The length (L) of each chopped carbon fiber bundle along the fiber direction of the carbon fiber bundle is from 1 mm to 50 mm (inclusive); the ratio of the longest diameter (Dmax) to the shortest diameter (Dmin) of a cross section perpendicular to the fiber direction of each chopped carbon fiber bundle, namely Dmax/Dmin is from 6.0 to 18.0 (inclusive); and the orientation parameter of the single fibers present in the surface of each chopped carbon fiber bundle is 4.0 or less.

A method for fabricating a carbon-bound lithium-ion conductor-carbon composite cathode material having a carbon fiber structure, comprising: mixing a carbon material, a lithium-ion conductor, an organic polymer material and an organic solvent, thereby obtaining a mixed slurry A; granulating and drying the mixed slurry A to obtain solid particles M; performing a high-temperature carbonization treatment on the solid particles M in an inert atmosphere, thereby obtaining a carbon-bound lithium-ion conductor-carbon composite cathode material having a carbon fiber structure.

A graphene silicone sticky sheet and compound structure using the same is provided. The graphene silicone with PU function group is used as substrate which is further combined with an adhering layer so as to form as a graphene silicone sticky sheet. Therefore, it is adhered to various application objects, especially clothes or wearing objects, such as an eye mask. Further, the graphene silicone can be combined with conductive wires which extend outwards and thus it can be made as electrode adhesive sheet or electric heating sheet.