Embodiments of a silicon heat-dissipation package for compact electronic devices are described. In one aspect, a device includes first and second silicon cover plates. The first silicon cover plate has a first primary side and a second primary side opposite the first primary side thereof. The second silicon cover plate has a first primary side and a second primary side opposite the first primary side thereof. The first primary side of the second silicon cover plate includes an indentation configured to accommodate an electronic device therein. The first primary side of the second silicon cover plate is configured to mate with the second primary side of the first silicon cover plate when the first silicon cover plate and the second silicon cover plate are joined together with the electronic device sandwiched therebetween.

The present application relates to EIC-INTEGRATED PICs. More particularly, various embodiments relate to EIC-INTEGRATED PICs enabling effective thermal management temperature control and heat removal.

A semiconductor structure is provided. The semiconductor structure includes: a fin heat-dissipation region on a substrate; a fin channel part on the fin heat-dissipation region, and an isolation structure on the substrate. A width of the fin channel part is smaller than a width of the fin heat-dissipation region. A top surface of the isolation structure is coplanar with a top surface of the fin heat-dissipation region.

The present application provides a method for fabricating a semiconductor device. The method includes providing a carrier substrate, forming through semiconductor vias in the carrier substrate for thermally conducting heat, forming a bonding layer on the carrier substrate, providing a first die structure including through semiconductor vias, forming an intervening bonding layer on the first die structure, bonding the first die structure onto the bonding layer through the intervening bonding layer, and bonding a second die structure onto the first die structure. The carrier substrate, the through semiconductor vias, and the bonding layer together configure a carrier structure. The second die structure and the first die structure are electrically coupled by the through semiconductor vias.

An integrated circuit semiconductor device includes a substrate having a first surface and a second surface opposite the first surface; a rail through via passing between the first surface and the second surface of the substrate; a cell-level portion arranged on the first surface and comprising a buried rail connected to the rail through via, a local conductive interconnect, a cell via connected to the local conductive interconnect, and a transistor connected to the local conductive interconnect; a signal wiring-level portion arranged on the cell-level portion and comprising a plurality of upper multi-layer interconnect layers connected to the local conductive interconnect via the cell via and upper vias connecting the upper multi-layer interconnect layers to each other; a dummy substrate arranged on the signal wiring-level portion; a bonding-level portion arranged between the signal wiring-level portion and the dummy substrate and bonding the signal wiring-level portion to the dummy substrate, and comprising a bonding pad connected to the upper via; a power delivery network-level portion arranged under the second surface of the substrate and comprising a plurality of lower multi-layer interconnect layers connected to the rail through via and lower vias connecting the lower multi-layer interconnect layers to each other; and an external connection terminal arranged under the power delivery network-level portion and connected to the lower multi-layer interconnect layers.

A method of fabricating a semiconductor package structure is provided. The structure is configured to include a base substrate, a die placed on the base substrate, the die including a semiconductor device, a solder bump placed on one surface of the die to exhaust heat generated in the die to an outside; and a solder ball placed on other surface of the die facing the one surface to transmit a signal, which is produced by the semiconductor device of the die, to an external device.

A bond layer including at least one metal region in a plan view is disposed on a surface layer portion of a substrate formed from a semiconductor. A semiconductor element is disposed on the bond layer and includes a first transistor disposed on a first metal region that is a metal region as the at least one metal region of the bond layer and including a collector layer electrically coupled to the first metal region, a base layer disposed on the collector layer, and an emitter layer disposed on the base layer. A first emitter electrode is disposed on the emitter layer of the first transistor. A first conductor protrusion is disposed on the first emitter electrode. The thermal conductivity of the semiconductor material of the surface layer portion is higher than that of each of the collector layer, the base layer, and the emitter layer of the first transistor.

A semiconductor structure is provided. The semiconductor structure includes: a fin heat-dissipation region on a substrate; a fin channel part on the fin heat-dissipation region, and an isolation structure on the substrate. A width of the fin channel part is smaller than a width of the fin heat-dissipation region. A top surface of the isolation structure is coplanar with a top surface of the fin heat-dissipation region.

An apparatus and a method of making are disclosed for an improved interposer comprises a wide bandgap semiconductor interposer such as silicon carbide (SiC) with a plurality of connectors formed in situ within the interposer for connecting the integrated circuit die to the substrate. The plurality of connectors may include carbon electrical connectors and/or optical wave guide connectors formed an angle within the interposer. The improved interposer may include a with the integrated circuit die disposed in the recess and thermally coupled to the silicon carbide (SiC) interposer for providing a heat sink for the integrated circuit die. A first and a second recess may be formed in separate surfaces of the silicon carbide (SiC) interposer enabling multiple interposers to be stacked upon one another.

An air cavity package includes a dielectric frame that is formed from an alumina ceramic, a polyimide, or a semi-crystalline thermoplastic. The dielectric frame is joined to a flange using a high temperature silicone adhesive. Leads may be bonded to the dielectric frame using a high temperature organic adhesive, a direct bond, or by brazing.