A microcapsule includes a shell including a conducting component; and a thermally expandable component contained in the shell and having a property of expanding by heating, the shell deforming due to expansion of the thermally expandable component to come in contact with another capsule and have a conducting state with the other capsule.

To enable a structure to be downsized, and to restrict a reduction in image quality. There is provided an electronic component including a circuit board having a first face, a second face opposite to the first face, and a first opening, a translucent member provide to oppose the first face of the circuit board, an imaging device flip-chip mounted on the second face of the circuit board and having a light receiving face on a side opposing the translucent member, and a light absorption member provided between the circuit board and the translucent member and formed in a region other than the first opening in plan view on the first face of the circuit board.

An affixation film 101 for a printed wiring board includes a circuit pattern concealing layer 112, and an adhesive layer 111 put on top of the circuit pattern concealing layer 112. An opposite surface of the circuit pattern concealing layer 112 from the adhesive layer 111 has an Rku of 2.5-3.0.

A semiconductor package of an embodiment includes a wiring substrate, a semiconductor chip provided on an upper surface of the wiring substrate, a sealing resin covering surfaces of the wiring substrate and the semiconductor chip, an infrared reflection layer containing any of aluminum, aluminum oxide, and titanium oxide, and an external terminal provided on a lower surface of the wiring substrate. The wiring substrate is electrically connectable with a printed wiring board through the external terminal. The infrared reflection layer is provided to the sealing resin on an upper side of a surface of the semiconductor chip on a side opposite to an upper surface of the wiring substrate.

A multilayer resin substrate includes a base material including stacked resin layers including an opening resin layer, a conductor pattern, and an interlayer connection conductor. A concave portion is provided in the base material. The opening resin layer is closer to a first main surface than other resin layers. The concave portion includes a first opening portion provided by a cutting process from one surface of the opening resin layer, and another resin layer. The interlayer connection conductor is provided by filling a conductor in a second opening portion provided by a cutting process from an opposite surface of the opening resin layer. The end portion of the one surface of the first opening portion is not in contact with the conductor pattern.

A component carrier for carrying and cooling at least one heat generating electronic component is presented. The component carrier comprising includes an outer layer structure, an electrically insulating layer arranged adjacent to the outer layer structure, and a heat conducting structure arranged adjacent to the electrically insulating layer on a side opposite to the outer layer structure. The heat conducting structure is thermally coupled to the at least one heat generating electronic component such that the outer layer structure receives thermal radiation irradiated by the heat conducting structure and transports corresponding heat away from the component carrier via convection by a heat transfer medium surrounding the component carrier.

A method for curing solder paste on a thermally fragile substrate is disclosed. An optically reflective layer and an optically absorptive layer are printed on a thermally fragile substrate. Multiple conductive traces are selectively deposited on the optically reflective layer and on the optically absorptive layer. Solder paste is then applied on selective locations that are corresponding to locations of the optically absorptive layer. After a component has been placed on the solder paste, the substrate is irradiated from one side with uniform pulsed light. The optically absorptive layer absorbs the pulsed light and becomes heated, and the heat is subsequently transferred to the solder paste and the cornponent via thermal conduction in order to heat and melt the solder paste.

An electronic device according to an embodiment includes a printed circuit board including a ground pad, an optical sensor disposed on the printed circuit board, and a shielding member covering the optical sensor. The shielding member includes a first adhesive layer attached on the optical sensor and the ground pad, a first shielding layer electrically connected to the ground pad and disposed on the first adhesive layer, and a first cover layer disposed on the first shielding layer, the first cover layer including a plurality of first particles configured to reflect or scatter light, a plurality of second particles configured to absorb the light, and a binder covering the plurality of first particles and the plurality of second particles.

An electroconductive substrate including a base material and a metal wiring made of at least either of silver and copper, and the electroconductive substrate has an antireflection region formed on part or all of the metal wiring surface. This antireflection region is composed of roughened particles made of at least either of silver and copper and blackened particles finer than the roughened particles and embedded between the roughened particles. The blackened particles are made of silver or a silver compound, copper or a copper compound, or carbon or an organic substance having a carbon content of 25 wt % or more. The antireflection region has a surface with a center line average roughness of 15 nm or more and 70 nm or less. The electroconductive substrate is formed from metal wiring from a metal ink that forms roughened particles, followed by application of a blackening ink containing blackened particles.

The present invention discloses a method for preparing a novel material layer structure of a circuit board, comprising the steps of: (1) combining a film with a copper layer to form an FCCL single-sided board; (2) applying a semi-cured functional material layer on a back side of the film of the FCCL single-sided board, wherein the semi-cured functional material layer is an MPI film, an LCP film, a TFP film, a PTFE film, a copper ion migration resistant film, an LDK high-frequency functional adhesive, a copper ion migration resistant adhesive, or a mixture of the LDK high-frequency functional adhesive and the copper ion migration resistant adhesive to form a novel material layer structure for a circuit board. An article prepared by performing the above methods is also disclosed. The prepared novel material layer structure of the circuit board has high-frequency characteristics and/or copper ion migration resistance, and can be used as an integral structure. In the circuit board manufacturing process, it can be manufactured as the circuit board manufacturing material to be different circuit board structures, which brings great convenience for subsequent circuit board manufacturing and simplifies the manufacturing process.