A non-woven film for electronic components is provided in the present disclosure. The non-woven film for electronic components includes a polyetherimide substrate and an aerogel. The aerogel is disposed on the polyetherimide substrate. The aerogel has a moisture content between 0.7% and 0.9% and a porosity between 85% and 95%.

A carbon fiber complex material for a carbon fiber reinforced plastic composite material includes a carbon fiber material formed from a continuous carbon fiber, and carbon nanowalls formed on a surface of the continuous carbon fiber.

One or more aspects of the present disclosure are directed to bladders that incorporate a multi-layer optical film that impart a structural color to the bladder. The present disclosure is also directed to articles including the bladders having a multi-layer optical film, and methods for making articles and bladders having a multi-layer optical film.

One or more aspects of the present disclosure are directed to bladders that incorporate a multi-layer optical film that impart a structural color to the bladder. The present disclosure is also directed to articles including the bladders having a multi-layer optical film, and methods for making articles and bladders having a multi-layer optical film.

Provided herein are methods for preparing metal coated textile substrate by ultrasonic irradiation deposition processes and products thereof.

An article. The article includes a nonwoven having a pH value from 2 to 6; wherein the article is a wound dressing.

An object of the present invention is to provide a coloring technique for fiber substrates, the technique being capable of imparting metallic luster and further reducing discoloration. The object can be achieved by a laminated sheet comprising a fiber substrate and a metal element- or metalloid element-containing layer, the fiber substrate holding a sealing material.

A method for converting amorphous carbon fiber to graphitized carbon fiber, the method comprising immersing the amorphous carbon fiber into a molten anhydrous alkaline earth salt (e.g., CaCl.sub.2) and/or MgCl.sub.2) maintained at a temperature within a range of 720° C.-920° C. or 780° C.-920° C. while the amorphous carbon fiber is cathodically polarized at a voltage within a range of −2.2V to −2.8V for a period of time (e.g., 0.5-6 hours) to result in conversion of the amorphous carbon fiber to the graphitized carbon fiber, wherein the graphitized carbon fiber is at least partially graphitized.

A method for converting amorphous carbon fiber to graphitized carbon fiber, the method comprising immersing the amorphous carbon fiber into a molten anhydrous alkaline earth salt (e.g., CaCl.sub.2) and/or MgCl.sub.2) maintained at a temperature within a range of 720° C.-920° C. or 780° C.-920° C. while the amorphous carbon fiber is cathodically polarized at a voltage within a range of −2.2V to −2.8V for a period of time (e.g., 0.5-6 hours) to result in conversion of the amorphous carbon fiber to the graphitized carbon fiber, wherein the graphitized carbon fiber is at least partially graphitized.

Disclosed is a method of manufacturing a graphene conductive fabric, which includes mixing a first solvent, a second solvent and nano-graphene sheets, dispersing the nano-graphene sheets with a mechanical force to form a graphene suspension solution; adding at least a curable resin to the graphene suspension solution, dispersing the nano-graphene sheets and the curable resin with the mechanical force to form a graphene resin solution; coating or printing the graphene resin solution on a hydrophobic protective layer, curing the graphene resin solution to form a graphene conductive layer adhered to the hydrophobic protective layer; coating a hot glue layer on the graphene conductive layer; and attaching a fibrous tissue on the hot glue layer, heating and pressing the fibrous tissue to allow the hot glue layer respectively adhere to the graphene conductive layer and the fibrous tissue.