A composite including a polymeric material or emulsion and biochar. The composite includes 1 wt % to 20 wt % of the biochar. Making the composite includes combining biochar with a polymeric material or emulsion to yield a modified polymeric material or emulsion, and homogenizing the modified polymeric material or emulsion to yield the composite. Functionalizing biochar includes removing contaminants from the biochar to yield decontaminated biochar, oxidizing the decontaminated biochar to yield oxidized biochar, and functionalizing the oxidized biochar. Making nitrogen-doped biochar includes combining urea and wood residue to form a mixture, and heating the mixture in an oxygen-free environment to form the nitrogen-doped biochar.

The formation method of graphene includes the steps of forming a layer including graphene oxide over a first conductive layer; and supplying a potential at which the reduction reaction of the graphene oxide occurs to the first conductive layer in an electrolyte where the first conductive layer as a working electrode and a second conductive layer with a as a counter electrode are immersed. A manufacturing method of a power storage device including at least a positive electrode, a negative electrode, an electrolyte, and a separator includes a step of forming graphene for an active material layer of one of or both the positive electrode and the negative electrode by the formation method.

The formation method of graphene includes the steps of forming a layer including graphene oxide over a first conductive layer; and supplying a potential at which the reduction reaction of the graphene oxide occurs to the first conductive layer in an electrolyte where the first conductive layer as a working electrode and a second conductive layer with a as a counter electrode are immersed. A manufacturing method of a power storage device including at least a positive electrode, a negative electrode, an electrolyte, and a separator includes a step of forming graphene for an active material layer of one of or both the positive electrode and the negative electrode by the formation method.

The present disclosure relates to a method for manufacturing graphene based on a mixed inorganic acid solvent. By using the inorganic acid solvent with simple preparation and low-cost instead of expensive organic solvent to perform a solvent stripping method for manufacturing graphene products, it may avoid the problems of high toxicity and harsh preparation conditions caused by using organic solvents, reduce the requirement on temperature in the graphene preparation process of the solvent stripping method, and reduce the time required by graphene stripping treatment; thereby simplifying the preparation process, and facilitating the commercialization and large-scale development of the method for manufacturing graphene by the solvent stripping method.

The present disclosure relates to a method for manufacturing graphene based on a mixed inorganic acid solvent. By using the inorganic acid solvent with simple preparation and low-cost instead of expensive organic solvent to perform a solvent stripping method for manufacturing graphene products, it may avoid the problems of high toxicity and harsh preparation conditions caused by using organic solvents, reduce the requirement on temperature in the graphene preparation process of the solvent stripping method, and reduce the time required by graphene stripping treatment; thereby simplifying the preparation process, and facilitating the commercialization and large-scale development of the method for manufacturing graphene by the solvent stripping method.

The present invention relates to organic or aqueous graphenium dispersions and composites, process for preparing the same, and uses thereof.

The present invention relates to organic or aqueous graphenium dispersions and composites, process for preparing the same, and uses thereof.

Proposed are a photocatalyst, including titanium dioxide particles including titanium dioxide (TiO.sub.2), a carbon material located on all or part of the surface of the titanium dioxide particles and including at least one selected from the group consisting of graphene, reduced graphene oxide (rGO), and carbon nanotubes (CNTs), and bimetallic nanoparticles supported on the carbon material and including first metal nanoparticles and second metal nanoparticles, and a water treatment method using the same. In the photocatalyst and the water treatment method using the same, the photocatalyst including bimetallic nanoparticles and graphene oxide is prepared, thereby exhibiting high reduction efficiency and high selectivity to nitrogen gas even without the use of an external electron donor.

Proposed are a photocatalyst, including titanium dioxide particles including titanium dioxide (TiO.sub.2), a carbon material located on all or part of the surface of the titanium dioxide particles and including at least one selected from the group consisting of graphene, reduced graphene oxide (rGO), and carbon nanotubes (CNTs), and bimetallic nanoparticles supported on the carbon material and including first metal nanoparticles and second metal nanoparticles, and a water treatment method using the same. In the photocatalyst and the water treatment method using the same, the photocatalyst including bimetallic nanoparticles and graphene oxide is prepared, thereby exhibiting high reduction efficiency and high selectivity to nitrogen gas even without the use of an external electron donor.

Provided are reduced acylated graphene oxide as an electrode active material and a method for preparing the same. By the method for preparing reduced acylated graphene oxide according to the present invention, a negative electrode active material for a lithium secondary battery having stable activity and a high battery capacity may be prepared with a simple and low-cost process. In addition, the active material prepared by the preparation method has low resistance, a high battery capacity, and improved rate-limiting characteristics while having stable cycle characteristics.