A method for forming a packaged electronic device includes providing a substrate having a first major surface and an opposing second major surface. The method includes attaching an electronic device to the first major surface of the substrate and providing a first conductive structure coupled to at least a first portion of the substrate. The method includes forming a dielectric layer overlying at least part of the first conductive structure. The method includes forming a conductive layer overlying the dielectric layer and connected to a second portion of the substrate. The first conductive structure, the dielectric layer, and conductive layer are configured as a capacitor structure and further configured as one or more of an enclosure structure or a stiffener structure for the packaged electronic device.

A method for forming a packaged electronic device includes providing a substrate having a first major surface and an opposing second major surface. The method includes attaching an electronic device to the first major surface of the substrate and providing a first conductive structure coupled to at least a first portion of the substrate. The method includes forming a dielectric layer overlying at least part of the first conductive structure. The method includes forming a conductive layer overlying the dielectric layer and connected to a second portion of the substrate. The first conductive structure, the dielectric layer, and conductive layer are configured as a capacitor structure and further configured as one or more of an enclosure structure or a stiffener structure for the packaged electronic device.

An anisotropic conductive film includes, as conductive particles for anisotropic conductive connection, metal particles such as solder particles having on the surface an oxide film. In this anisotropic conductive film, the metal particles are contained in an insulating film and regularly arranged as viewed in a plan view. A flux is disposed to be in contact with, or in proximity to, at least one of ends of the metal particles on a front surface side of the anisotropic conductive film and a rear surface side of the anisotropic conductive film. Preferable metal particles are solder particles. Preferably, the insulating film has a structure of two layers, and the metal particles are disposed between the two layers.

An anisotropic conductive film includes, as conductive particles for anisotropic conductive connection, metal particles such as solder particles having on the surface an oxide film. In this anisotropic conductive film, the metal particles are contained in an insulating film and regularly arranged as viewed in a plan view. A flux is disposed to be in contact with, or in proximity to, at least one of ends of the metal particles on a front surface side of the anisotropic conductive film and a rear surface side of the anisotropic conductive film. Preferable metal particles are solder particles. Preferably, the insulating film has a structure of two layers, and the metal particles are disposed between the two layers.

Provided is a multilayer substrate including laminated semiconductor substrates each having a penetrating hole (hereinafter referred to as through hole) having a plated film formed in the inner surface. The multilayer substrate has excellent conduction characteristics and can be manufactured at low cost. Conductive particles are selectively present at a position where the through holes face each other as viewed in a plan view of the multilayer substrate. The multilayer substrate has a connection structure in which the facing through holes are connected by the conductive particles, and the semiconductor substrates each having the through hole are bonded by an insulating adhesive.

Provided is a multilayer substrate including laminated semiconductor substrates each having a penetrating hole (hereinafter referred to as through hole) having a plated film formed in the inner surface. The multilayer substrate has excellent conduction characteristics and can be manufactured at low cost. Conductive particles are selectively present at a position where the through holes face each other as viewed in a plan view of the multilayer substrate. The multilayer substrate has a connection structure in which the facing through holes are connected by the conductive particles, and the semiconductor substrates each having the through hole are bonded by an insulating adhesive.

A semiconductor package includes a semiconductor chip disposed over a first main surface of a first substrate, a package lid disposed over the semiconductor chip, and spacers extending from the package lid through corresponding holes in the first substrate. The spacers enter the holes at a first main surface of the first substrate and extend beyond an opposing second main surface of the first substrate.

A semiconductor package includes a semiconductor chip disposed over a first main surface of a first substrate, a package lid disposed over the semiconductor chip, and spacers extending from the package lid through corresponding holes in the first substrate. The spacers enter the holes at a first main surface of the first substrate and extend beyond an opposing second main surface of the first substrate.

A wafer-to-wafer bonding structure includes a first wafer including a first conductive pad in a first insulating layer and a first barrier layer surrounding a lower surface and side surfaces of the first conductive pad, a second wafer including a second conductive pad in a second insulating layer and a second barrier layer surrounding a lower surface and side surfaces of the second conductive pad, the second insulating layer being bonded to the first insulating layer, and at least a portion of an upper surface of the second conductive pad being partially or entirely bonded to at least a portion of an upper surface of the first conductive pad, and a third barrier layer between portions of the first and second wafers where the first and second conductive pads are not bonded to each other.

A thermal management solution in a mobile computing system is bonded to an integrated circuit component by a thermal interface material layer (TIM layer) that does not require the application of a permanent force to ensure a reliable thermally conductive connection. A leaf spring or other loading mechanism that can apply a permanent force to a TIM layer can be secured to a printed circuit board by fasteners that extend through holes in the board in the vicinity of the integrated circuit component. These holes consume area that could otherwise be used for signal routing. In devices that use a TIM layer that does not require the application of a permanent force, the thermal management solution can be attached to a printed circuit board or chassis at a location remote to the integrated circuit component, where the attachment mechanism does not or minimally interferes with integrated circuit component signal routing.