A conductive sheet according to an aspect of the present invention includes a first nanostructure and a second nanostructure disposed to intersect each other. A thickness of an intersect region of the first nanostructure and the second nanostructure is 0.6 to 0.9 times the sum of thicknesses of non-intersection regions of the first nanostructure and the second nanostructure.

A stretchable wiring body includes: a conductor that includes a binder and conductive particles dispersed in the binder; and soft resins that are embedded in the binder and are softer than the binder. The conductive particles are not covered with the soft resins.

The development of stretchable, mechanically and electrically robust interconnects by printing an elastic, silver-based composite ink onto stretchable fabric. Such interconnects can have conductivity of 3000-4000 S/cm and are durable under cyclic stretching. In serpentine shape, the fabric-based conductor is enhanced in electrical durability. Resistance increases only ˜5 times when cyclically stretched over a thousand times from zero to 30% strain at a rate of 4% strain per second due to the ink permeating the textile structure. The textile fibers are wetted with composite ink to form a conductive, stretchable cladding of the silver particles. The e-textile can realize a fully printed, double-sided electronic system of sensor-textile-interconnect integration. The double-sided e-textile can be used for a surface electromyography (sEMG) system to monitor muscles activities, an electroencephalography (EEG) system to record brain waves, and the like.

The present invention relates to a heat dissipating device disposed on a circuit board. The heat dissipating device is provided with a first glue layer, a first graphene composite heat dissipating layer, a second glue layer, a second graphene composite heat dissipating layer, and a resin layer in this order from bottom to top. Furthermore, the first graphene composite heat dissipating layer and the second graphene composite heat dissipating layer are doped with a plurality of metal particles, and the first graphene composite heat dissipating layer and the second graphene composite heat dissipating layer are respectively covered by a metal layer. The above structure is simple, space-saving, and has good thermal conductivity.

The development of stretchable, mechanically and electrically robust interconnects by printing an elastic, silver-based composite ink onto stretchable fabric. Such interconnects can have conductivity of 3000-4000 S/cm and are durable under cyclic stretching. In serpentine shape, the fabric-based conductor is enhanced in electrical durability. Resistance increases only ˜5 times when cyclically stretched over a thousand times from zero to 30% strain at a rate of 4% strain per second due to the ink permeating the textile structure. The textile fibers are ‘wetted’ with composite ink to form a conductive, stretchable cladding of the silver particles. The e-textile can realize a fully printed, double-sided electronic system of sensor-textile-interconnect integration. The double-sided e-textile can be used for a surface electromyography (sEMG) system to monitor muscles activities, an electroencephalography (EEG) system to record brain waves, and the like.

An inductor component includes a main body formed in a flat-plate shape and including a magnetic layer; an inductor wiring line disposed on a plane inside the main body; a first vertical wiring line that extends, from a pad portion which is an end portion of the inductor wiring line, in a first direction to pass through the inside of the main body, and is exposed on a first principal surface side of the main body; a second vertical wiring line that extends, from the pad portion of the inductor wiring line, in a second direction to pass through the inside of the main body, and is exposed on a second principal surface side of the main body; and an insulation layer of a non-magnetic body. The first vertical wiring line includes a via conductor and a columnar wiring line. The second vertical wiring line includes a columnar wiring line.

A circuit board structure that includes a resin-based conductive adhesive layer is disclosed, in which a conductive layer is arranged between a first circuit board and a second circuit board. The conductive layer includes a first conductive paste layer and the resin-based conductive adhesive layer is formed on the first conductive paste layer. The resin-based conductive adhesive layer contains a sticky resin material and a plurality of conductive particles distributed in the sticky resin material. The plurality of conductive particles establish an electrical connection between the first conductive paste layer and the resin-based conductive adhesive layer.

A sheet-shaped stretchable structure including stretchable resin sheets laminated together is provided. A conductive layer may be disposed at least at one of several positions. For example, the conductive layer may be disposed between any two adjacent ones of the laminated stretchable resin sheets. The conductive layer may be disposed on a top surface of an uppermost one of the laminated stretchable resin sheets. Further, the conductive layer may be disposed on a bottom surface of a lowermost one of the laminated stretchable resin sheets, and a via hole.

A flexible printed circuit board includes: an electrically insulating substrate layer; an electrically conductive pattern stacked on at least one surface of the substrate layer; and a cover layer that is disposed on a stack including the substrate layer and the electrically conductive pattern and covers a surface of the stack, which surface is on the side on which the electrically conductive pattern is present. The electrically conductive pattern has a coil region including a coil. In the substrate layer or the cover layer, a high-magnetic permeability member is present in at least a region that overlaps the coil region in plan view.

This invention relates to a curable adhesive composition. In particular, the present invention relates to a curable adhesive composition for die attach, which eliminates the void issue, minimizes the fillet, and has lower bond line thickness and tilt trend, when cured.