Disclosed herein are composite materials comprising a siliconized carbon fiber fabric and polymeric sizing. In one embodiment, the polymeric sizing can be bismaleimide, an epoxy resin, or both. In another embodiment, the composite materials possess mechanical strength and durability and acceptable performance after extended periods of time in storage. In another embodiment, disclosed herein is a method for making the composite materials, the method including at least the steps of (a) siliconizing the carbon fiber fabric to produce a siliconized carbon fiber fabric; and (b) applying a polymeric sizing material to the siliconized carbon fiber fabric to create the composite material. In yet another embodiment, disclosed herein are composite materials formed by the disclosed process and articles comprising the composite materials including, but not limited to, camping equipment, military equipment, clothing, sporting equipment, aerospace equipment, wrinkle-free fabric, or any combination thereof.

Disclosed herein are composite materials comprising a siliconized carbon fiber fabric and polymeric sizing. In one embodiment, the polymeric sizing can be bismaleimide, an epoxy resin, or both. In another embodiment, the composite materials possess mechanical strength and durability and acceptable performance after extended periods of time in storage. In another embodiment, disclosed herein is a method for making the composite materials, the method including at least the steps of (a) siliconizing the carbon fiber fabric to produce a siliconized carbon fiber fabric; and (b) applying a polymeric sizing material to the siliconized carbon fiber fabric to create the composite material. In yet another embodiment, disclosed herein are composite materials formed by the disclosed process and articles comprising the composite materials including, but not limited to, camping equipment, military equipment, clothing, sporting equipment, aerospace equipment, wrinkle-free fabric, or any combination thereof.

Disclosed herein is a composition having a plurality of particles of a filler material and crosslinking units having the formula —(SiR—CH.sub.2—CH.sub.2—CH.sub.2)—. The silicon atom in the crosslinking unit is directly or indirectly bound to the filler material. Each R is alkyl, alkenyl, phenyl, methyl, ethyl, allyl, halogen, chloro, or bromo. Also disclosed herein is a filler material having the silicon atom of a silacyclobutane group is directly or indirectly bound thereto. Also disclosed herein is a method of crosslinking silacyclobutane groups bound to a plurality of particles of a filler material. The silicon atom of the silacyclobutane group is directly or indirectly bound to the filler material. Also disclosed herein is a composition including a plurality of fibers of a polymer having reactive oxygen atoms and siloxane groups. Coordination bonds are formed between the oxygen atoms and the silicon atoms of the siloxane groups of separate fibers.

Disclosed herein is a composition having a plurality of particles of a filler material and crosslinking units having the formula —(SiR—CH.sub.2—CH.sub.2—CH.sub.2)—. The silicon atom in the crosslinking unit is directly or indirectly bound to the filler material. Each R is alkyl, alkenyl, phenyl, methyl, ethyl, allyl, halogen, chloro, or bromo. Also disclosed herein is a filler material having the silicon atom of a silacyclobutane group is directly or indirectly bound thereto. Also disclosed herein is a method of crosslinking silacyclobutane groups bound to a plurality of particles of a filler material. The silicon atom of the silacyclobutane group is directly or indirectly bound to the filler material. Also disclosed herein is a composition including a plurality of fibers of a polymer having reactive oxygen atoms and siloxane groups. Coordination bonds are formed between the oxygen atoms and the silicon atoms of the siloxane groups of separate fibers.

An additive for incorporating ultraviolet radiation protection into a synthetic polymer with the additive and the synthetic polymer for forming a synthetic material is disclosed which has a quantity of zinc oxide particles modified with a layer of a reactive group that forms a bond with a synthetic polymer having C-H bonds.

Processes for making weather resistant, slow-decaying, durable natural fiber/coir geotextiles produce geotextiles having flexibility, permeability, light weight and cost-effective characteristics. In this process an in situ chemical grafting using a mixture of Cashew Nut Shell Liquid and aminoalkyl trialkoxysilanes with cellulose was done followed by curing in presence of sunlight, UV light or heat. The developed product showed durability and strength more than that of natural fiber/fabric and retaining natural fiber/fabric/geotextiles characteristics. The geotextiles have delayed bio-deterioration having wider long-term end use/applications. This process of making durable geotextiles is eco-friendly and retains the desired characteristic.

A product for incorporating ultraviolet radiation protection and antimicrobial protection into a synthetic polymer is disclosed which has a quantity of zinc oxide particles modified with a layer of a reactive group that forms a bond with a quantity of synthetic polymer chips having C—H bonds. A product for incorporating ultraviolet radiation protection and antimicrobial protection into a synthetic polymer prior to forming a synthetic material is also disclosed which has a quantity of synthetic polymer chips and a quantity of zinc oxide particles modified with a layer of a reactive group that forms a bond with the quantity of the synthetic polymer chips.

A product for incorporating ultraviolet radiation protection and antimicrobial protection into a synthetic polymer is disclosed which has a quantity of zinc oxide particles with each particle having a surface, a paste, a quantity of synthetic polymer chips, and a quantity of a reactive group for modifying each surface of each zinc oxide particle, the quantity of the reactive group sufficient for forming a bond with the quantity of synthetic polymer chips prior to the quantity of synthetic polymer chips being formed into a fiber.

A product for incorporating ultraviolet radiation protection and antimicrobial protection into a synthetic polymer is disclosed which has a quantity of zinc oxide particles modified with a layer of a reactive group that forms a bond with a quantity of synthetic polymer chips having C—H bonds. A product for incorporating ultraviolet radiation protection and antimicrobial protection into a synthetic polymer prior to forming a synthetic material is also disclosed which has a quantity of synthetic polymer chips and a quantity of zinc oxide particles modified with a layer of a reactive group that forms a bond with the quantity of the synthetic polymer chips.

A product having ultraviolet radiation protection and antimicrobial protection has a quantity of synthetic material, a quantity of zinc oxide particles with each particle having a surface, the quantity of zinc oxide particles in the range of 0.05 percent to 0.10 percent, and a quantity of a reactive group for modifying each surface of each zinc oxide particle, the quantity of the reactive group for incorporating the quantity of zinc oxide particles into the quantity of synthetic material prior to the quantity of synthetic material being formed into a fiber.