A method for preparing a bonding component comprises mixing a first solution comprising an organofluorine monomer unit with a second solution comprising an organosilicon monomer unit to form, in-situ, a copolymer solution comprising a copolymer of an organofluorine polymer and an organosilicon polymer based on the organofluorine monomer unit and the organosilicon monomer unit. The method further comprises depositing the copolymer solution onto a body to form a film of the copolymer, and curing the film of the copolymer.

A method for preparing a bonding component comprises mixing a first solution comprising an organofluorine monomer unit with a second solution comprising an organosilicon monomer unit to form, in-situ, a copolymer solution comprising a copolymer of an organofluorine polymer and an organosilicon polymer based on the organofluorine monomer unit and the organosilicon monomer unit. The method further comprises depositing the copolymer solution onto a body to form a film of the copolymer, and curing the film of the copolymer.

A method for preparing a bonding component comprises mixing a first solution comprising an organofluorine monomer unit with a second solution comprising an organosilicon monomer unit to form, in-situ, a copolymer solution comprising a copolymer of an organofluorine polymer and an organosilicon polymer based on the organofluorine monomer unit and the organosilicon monomer unit. The method further comprises depositing the copolymer solution onto a body to form a film of the copolymer, and curing the film of the copolymer.

A fluororubber composition containing a ternary fluororubber polymer including vinylidene fluoride, perfluorovinyl ether and tetrafluoroethylene; a reaction product of silica-aluminum silicate with vinyl ethoxysilane; and hydrotalcite. The fluororubber composition does not substantially contain magnesium oxide and calcium hydroxide. The fluororubber composition contains 2 to 55 parts by weight of the reaction product of silica-aluminum silicate with vinyl ethoxysilane and 0.5 to 10 parts by weight of the hydrotalcite relative to 100 parts by weight of the ternary fluororubber polymer.

A fluororubber composition containing a ternary fluororubber polymer including vinylidene fluoride, perfluorovinyl ether and tetrafluoroethylene; a reaction product of silica-aluminum silicate with vinyl ethoxysilane; and hydrotalcite. The fluororubber composition does not substantially contain magnesium oxide and calcium hydroxide. The fluororubber composition contains 2 to 55 parts by weight of the reaction product of silica-aluminum silicate with vinyl ethoxysilane and 0.5 to 10 parts by weight of the hydrotalcite relative to 100 parts by weight of the ternary fluororubber polymer.

A copolymerized high temperature bonding component that includes a first amount of an organofluorine polymer and a second amount of an organosilicon polymer which are chemically bound to each other to form a copolymer. The bonding component may have properties that allow it to be used for binding dissimilar materials.

A copolymerized high temperature bonding component that includes a first amount of an organofluorine polymer and a second amount of an organosilicon polymer which are chemically bound to each other to form a copolymer. The bonding component may have properties that allow it to be used for binding dissimilar materials.

A copolymerized high temperature bonding component that includes a first amount of an organofluorine polymer and a second amount of an organosilicon polymer which are chemically bound to each other to form a copolymer. The bonding component may have properties that allow it to be used for binding dissimilar materials.

A composite is provided including metal chalcogenide nanotubes as the dispersed phase in a polymeric matrix, in which the polymeric matrix may be a fluoropolymer, urethane (e.g., polyurethane), sulfonic polymer, as well as epoxy and acrylic polymers for adhesive applications, such as pressure sensitive adhesives.

A composite is provided including metal chalcogenide nanotubes as the dispersed phase in a polymeric matrix, in which the polymeric matrix may be a fluoropolymer, urethane (e.g., polyurethane), sulfonic polymer, as well as epoxy and acrylic polymers for adhesive applications, such as pressure sensitive adhesives.