A single use invertible elastomeric article with at least two polymeric layers. Each polymer in the two polymeric layers is a single, pure polymer and are different from each other, such that the single polymer of the first layer is not the same as the single polymer of the second layer. The first layer can comprise acrylonitrile butadiene and the second layer can comprise polychloroprene in an embodiment. The first layer is directly bonded to the second layer with a primer coating between the layers comprising a cationic polymer. There is a method of manufacturing the invertible elastomeric article comprising the steps of coating a former with a coagulant; applying a first polymeric coating of a single polymer; coating the first polymeric coating with a primer; and applying a second polymeric coating; the second polymeric coating comprises a single polymer different from the single polymer of the first polymeric coating.

A single use invertible elastomeric article with at least two polymeric layers. Each polymer in the two polymeric layers is a single, pure polymer and are different from each other, such that the single polymer of the first layer is not the same as the single polymer of the second layer. The first layer can comprise acrylonitrile butadiene and the second layer can comprise polychloroprene in an embodiment. The first layer is directly bonded to the second layer with a primer coating between the layers comprising a cationic polymer. There is a method of manufacturing the invertible elastomeric article comprising the steps of coating a former with a coagulant; applying a first polymeric coating of a single polymer; coating the first polymeric coating with a primer; and applying a second polymeric coating; the second polymeric coating comprises a single polymer different from the single polymer of the first polymeric coating.

Disclosed are a self-exposure method for a surface of conductive particles anchored in a polymer layer, a method of fabricating an anisotropic conductive film using the self-exposure method, and the anisotropic conductive film. A self-exposure method for a surface of conductive particles within a polymer layer may include controlling surface energy of multiple conductive particles so that a difference between surface energy of polymer to be used to fabricate the polymer layer and surface energy of the multiple conductive particles to be included in the polymer layer is a preset difference or more, forming a polymer solution by dissolving the polymer into a solvent in which the conductive particles having controlled surface energy have been mixed, and generating the polymer layer from which at least part of a surface of the multiple conductive particles has been externally exposed due to a difference in the surface energy by drying the polymer solution.

Disclosed are a self-exposure method for a surface of conductive particles anchored in a polymer layer, a method of fabricating an anisotropic conductive film using the self-exposure method, and the anisotropic conductive film. A self-exposure method for a surface of conductive particles within a polymer layer may include controlling surface energy of multiple conductive particles so that a difference between surface energy of polymer to be used to fabricate the polymer layer and surface energy of the multiple conductive particles to be included in the polymer layer is a preset difference or more, forming a polymer solution by dissolving the polymer into a solvent in which the conductive particles having controlled surface energy have been mixed, and generating the polymer layer from which at least part of a surface of the multiple conductive particles has been externally exposed due to a difference in the surface energy by drying the polymer solution.

According to one embodiment, a nonaqueous electrolyte secondary battery includes a positive electrode, a negative electrode, and a nonaqueous electrolyte. The negative electrode includes a negative electrode current collector and a negative electrode mixed-material layer on the negative electrode current collector. The negative electrode mixed-material layer includes a titanium-containing metal oxide and a binder including an acrylic resin. The negative electrode satisfies />1.3610.sup.2, where is a peel strength (N/m) between the current collector and the negative electrode mixed-material layer, and is a cutting strength (N/m) according to a surface and interfacial cutting method in the negative electrode mixed-material layer.

According to one embodiment, a nonaqueous electrolyte secondary battery includes a positive electrode, a negative electrode, and a nonaqueous electrolyte. The negative electrode includes a negative electrode current collector and a negative electrode mixed-material layer on the negative electrode current collector. The negative electrode mixed-material layer includes a titanium-containing metal oxide and a binder including an acrylic resin. The negative electrode satisfies />1.3610.sup.2, where is a peel strength (N/m) between the current collector and the negative electrode mixed-material layer, and is a cutting strength (N/m) according to a surface and interfacial cutting method in the negative electrode mixed-material layer.

According to one embodiment, a nonaqueous electrolyte secondary battery includes a positive electrode, a negative electrode, and a nonaqueous electrolyte. The negative electrode includes a negative electrode current collector and a negative electrode mixed-material layer on the negative electrode current collector. The negative electrode mixed-material layer includes a titanium-containing metal oxide and a binder including an acrylic resin. The negative electrode satisfies />1.3610.sup.2, where is a peel strength (N/m) between the current collector and the negative electrode mixed-material layer, and is a cutting strength (N/m) according to a surface and interfacial cutting method in the negative electrode mixed-material layer.

The present application relates to a pinning composition, a laminate comprising the same, and a method for producing the same. The pinning composition of the present application can impart directionality and location selection properties to a polymer membrane comprising a self-assembly structure of a block copolymer. The pinning composition of the present application exhibits excellent reaction selectivity, whereby it can form a vertical lamella structure with a high degree of alignment. In addition, the pinning composition of the present application may be suitable for application to low temperature processes.

The present application relates to a pinning composition, a laminate comprising the same, and a method for producing the same. The pinning composition of the present application can impart directionality and location selection properties to a polymer membrane comprising a self-assembly structure of a block copolymer. The pinning composition of the present application exhibits excellent reaction selectivity, whereby it can form a vertical lamella structure with a high degree of alignment. In addition, the pinning composition of the present application may be suitable for application to low temperature processes.

The present invention relates to a solution or ink composition for fabricating high-performance thin-film transistors. The solution or ink comprises an organic semiconductor and a mediating polymer such as polyacrylonitrile, polystyrene, or the like or mixture thereof, in an organic solvent such as chlorobenzene or dichlorobenzene. The percentage ratio by weight of semiconductor:mediating polymer ranges from 5:95 to 95:5, and preferably from 20:80 to 80:20. The solution or ink is used to fabricate via solution coating or printing a semiconductor film, followed by drying and thermal annealing if necessary to provide a channel semiconductor for organic thin-film transistors (OTFTs). The resulting OTFT device with said channel semiconductor has afforded OTFT performance, particularly field-effect mobility and current on/off ratio that are superior to those OTFTs with channel semiconductors fabricated without a mediating polymer.