A method of manufacturing a flexible electronic device is described. The method comprises arranging an electronic component on a temporary carrier, providing a flexible laminate comprising an adhesive layer, pressing the temporary carrier and the flexible laminate together with the adhesive layer facing the temporary carrier such that the electronic component is pushed into the adhesive layer, and removing the temporary carrier. Further, a corresponding flexible electronic device is described.

A method of manufacturing a flexible electronic device is described. The method comprises arranging an electronic component on a temporary carrier, providing a flexible laminate comprising an adhesive layer, pressing the temporary carrier and the flexible laminate together with the adhesive layer facing the temporary carrier such that the electronic component is pushed into the adhesive layer, and removing the temporary carrier. Further, a corresponding flexible electronic device is described.

A circuit board structure includes a circuit board and an adhesive layer. The circuit board has a first board surface and an opposite second board surface, and the first board surface defines a predetermined portion. The circuit board has a conductive circuit disposed on the first board surface and at least partially arranged on the predetermined portion. The adhesive layer is seamlessly formed on the predetermined portion of the first board surface of the circuit board, and the conductive circuit arranged on the predetermined portion is seamlessly covered by the adhesive layer. A surface of the adhesive layer arranged away from the circuit board is a planar bonding surface.

A circuit board structure includes a circuit board and an adhesive layer. The circuit board has a first board surface and an opposite second board surface, and the first board surface defines a predetermined portion. The circuit board has a conductive circuit disposed on the first board surface and at least partially arranged on the predetermined portion. The adhesive layer is seamlessly formed on the predetermined portion of the first board surface of the circuit board, and the conductive circuit arranged on the predetermined portion is seamlessly covered by the adhesive layer. A surface of the adhesive layer arranged away from the circuit board is a planar bonding surface.

A multilayer curable resin film comprising a first resin layer comprising a first curable resin composition including a polyphenylene ether oligomer (A1) with an end modified by an aromatic vinyl group and a curing agent (A2) and a second resin layer comprising a second curable resin composition including an alicyclic olefin polymer (B1) and a curing agent (B2), a prepreg comprised of this including a fiber substrate, and a laminate, cured product, composite, and multilayer circuit board obtained using these are provided.

A multilayer curable resin film comprising a first resin layer comprising a first curable resin composition including a polyphenylene ether oligomer (A1) with an end modified by an aromatic vinyl group and a curing agent (A2) and a second resin layer comprising a second curable resin composition including an alicyclic olefin polymer (B1) and a curing agent (B2), a prepreg comprised of this including a fiber substrate, and a laminate, cured product, composite, and multilayer circuit board obtained using these are provided.

A semiconductor device substrate includes a front section and back section that are laminated cores disposed on a front- and back surfaces of a first core. The first core has a cylindrical plated through hole that has been metal plated and filled with air-core material. The front- and back sections have laser-drilled tapered vias that are filled with conductive material and that are coupled to the plated through hole. The back section includes an integral inductor coil that communicates to the front section. The first core and the laminated-cores form a hybrid-core semiconductor device substrate with an integral inductor coil.

Techniques for forming highly stretchable electronic interconnect devices are disclosed herein. In one embodiment, a method of fabricating an electronic interconnect device includes forming a layer of an adhesion material onto a surface of a substrate material capable of elastic and/or plastic deformation. The formed layer of the adhesion material has a plurality of adhesion material portions separated from one another on the surface of the substrate material. The method also includes depositing a layer of an interconnect material onto the formed layer of the adhesion material. The deposited interconnect material has regions that are not bonded or loosely bonded to corresponding regions of the substrate material, such that the interconnect material may be deformed more than the adhesion material attached to the substrate material. In certain embodiments, the interconnect material can also include a plurality of wrinkles on a surface facing away from the substrate material.

Techniques for forming highly stretchable electronic interconnect devices are disclosed herein. In one embodiment, a method of fabricating an electronic interconnect device includes forming a layer of an adhesion material onto a surface of a substrate material capable of elastic and/or plastic deformation. The formed layer of the adhesion material has a plurality of adhesion material portions separated from one another on the surface of the substrate material. The method also includes depositing a layer of an interconnect material onto the formed layer of the adhesion material. The deposited interconnect material has regions that are not bonded or loosely bonded to corresponding regions of the substrate material, such that the interconnect material may be deformed more than the adhesion material attached to the substrate material. In certain embodiments, the interconnect material can also include a plurality of wrinkles on a surface facing away from the substrate material.

An ink layer of an electrically conductive ink is formed on a sheet-like base and then the base is bent-deformed before the ink layer is cured, followed by curing the ink layer, thereby forming wiring. The ink layer is pliable during the bending deformation of the base, preventing breakage of the ink layer associated with the bending deformation of the base, and preventing damage to the wiring even when the wiring is finely formed.