A semiconductor device includes a wiring board; a first semiconductor chip including a first surface, a second surface, and a connection bump on the first surface, the first semiconductor chip coupled to the wiring board through the connection bump; a resin layer covering the connection bump between the first semiconductor chip and the wiring board, an upper surface of the resin layer parallel to the second surface of the first semiconductor chip; and a second semiconductor chip including a third surface, a fourth surface, and an adhesive layer on the third surface, the second semiconductor chip adhering to the second surface of the first semiconductor chip and the upper surface of the resin layer through the adhesive layer. The upper surface of the resin layer projects outside a portion of at least an outer edge of the second semiconductor chip when viewed from the top.

A semiconductor device includes a wiring board; a first semiconductor chip including a first surface, a second surface, and a connection bump on the first surface, the first semiconductor chip coupled to the wiring board through the connection bump; a resin layer covering the connection bump between the first semiconductor chip and the wiring board, an upper surface of the resin layer parallel to the second surface of the first semiconductor chip; and a second semiconductor chip including a third surface, a fourth surface, and an adhesive layer on the third surface, the second semiconductor chip adhering to the second surface of the first semiconductor chip and the upper surface of the resin layer through the adhesive layer. The upper surface of the resin layer projects outside a portion of at least an outer edge of the second semiconductor chip when viewed from the top.

A method for manufacturing a semiconductor structure includes: forming a first bonding layer on a device substrate formed with a semiconductor device so as to cover the semiconductor device, wherein the first bonding layer includes a first metal oxide material in an amorphous state; forming a second bonding layer on a carrier substrate, wherein the second bonding layer includes a second metal oxide material in an amorphous state; conducting a surface modification process on the first bonding layer and the second bonding layer; bonding the device substrate and the carrier substrate to each other through the first and second bonding layers; and annealing the first and second bonding layers so as to convert the first and second metal oxide materials from the amorphous state to a crystalline state.

A method may include the steps of directly bonding a semiconductor device having a substrate to an element; and removing a portion of the substrate to expose a remaining portion of the semiconductor device after bonding. The element may include one of a substrate used for thermal spreading, impedance matching or for RF isolation, an antenna, and a matching network comprised of passive elements. A second thermal spreading substrate may be bonded to the remaining portion of the semiconductor device. Interconnections may be made through the first or second substrates. The method may also include bonding a plurality of semiconductor devices to an element, and the element may have recesses in which the semiconductor devices are disposed.

A method may include the steps of directly bonding a semiconductor device having a substrate to an element; and removing a portion of the substrate to expose a remaining portion of the semiconductor device after bonding. The element may include one of a substrate used for thermal spreading, impedance matching or for RF isolation, an antenna, and a matching network comprised of passive elements. A second thermal spreading substrate may be bonded to the remaining portion of the semiconductor device. Interconnections may be made through the first or second substrates. The method may also include bonding a plurality of semiconductor devices to an element, and the element may have recesses in which the semiconductor devices are disposed.

A semiconductor device has a pre-molded discrete electrical component and a first encapsulant deposited over the pre-molded discrete electrical component. A first conductive layer is formed over the first encapsulant and pre-molded discrete electrical component. An electrical component is disposed over the first conductive layer. A second encapsulant is deposited over the electrical component and first conductive layer. A second conductive layer is formed over the second encapsulant. A conductive pillar is formed between the first conductive layer and second conductive layer through the second encapsulant. The pre-molded discrete electrical component has a discrete component and a third encapsulant deposited around the discrete component. The discrete component has an electrical terminal, a finish formed over the electrical terminal, and a third conductive layer formed over the finish. An interconnect structure formed on the electrical component is oriented toward the first conductive layer or the second conductive layer.

A device integration method and integrated device. The method may include the steps of directly bonding a semiconductor device having a substrate to an element; and removing a portion of the substrate to expose a remaining portion of the semiconductor device after bonding. The element may include one of a substrate used for thermal spreading, impedance matching or for RF isolation, an antenna, and a matching network comprised of passive elements. A second thermal spreading substrate may be bonded to the remaining portion of the semiconductor device. Interconnections may be made through the first or second substrates. The method may also include bonding a plurality of semiconductor devices to an element, and the element may have recesses in which the semiconductor devices are disposed. A conductor array having a plurality of contact structures may be formed on an exposed surface of the semiconductor device, vias may be formed through the semiconductor device to device regions, and interconnection may be formed between said device regions and said contact structures.

A method for manufacturing a semiconductor structure includes: forming a first bonding layer on a device substrate formed with a semiconductor device so as to cover the semiconductor device, wherein the first bonding layer includes a first metal oxide material in an amorphous state; forming a second bonding layer on a carrier substrate, wherein the second bonding layer includes a second metal oxide material in an amorphous state; conducting a surface modification process on the first bonding layer and the second bonding layer; bonding the device substrate and the carrier substrate to each other through the first and second bonding layers; and annealing the first and second bonding layers so as to convert the first and second metal oxide materials from the amorphous state to a crystalline state.