An optoelectronic device includes an optical integrated circuit having a first surface and a second surface opposite the first surface. The optical integrated circuit has an optical zone of the first surface of the optical integrated circuit. The device includes an electrically insulating material disposed over the optical integrated circuit, where he electrically insulating material partially covers the first surface so as to expose the optical zone.

Embodiments disclosed herein include electronic packages and methods of fabricating electronic packages. In an embodiment, an electronic package comprises an interposer, where a cavity passes through the interposer, and a nested component in the cavity. In an embodiment, the electronic package further comprises a die coupled to the interposer by a first interconnect and coupled to the nested component by a second interconnect. In an embodiment, the first and second interconnects comprise a first bump, a bump pad over the first bump, and a second bump over the bump pad.

The present disclosure provides a method for manufacturing a semiconductor structure. The semiconductor structure includes a substrate; a pad disposed over the substrate; a first passivation disposed over the substrate, partially covering the pad, and including a protrusion protruded from the first passivation and away from the substrate; a conductive layer disposed over the first passivation and a portion of the pad exposed from the first passivation; and a second passivation disposed over the conductive layer, wherein the conductive layer disposed over the protrusion is exposed from the second passivation.

Embodiments of the present disclosure include semiconductor packages and methods of forming the same. An embodiment is a semiconductor package including a first package including one or more dies, and a redistribution layer coupled to the one or more dies at a first side of the first package with a first set of bonding joints. The redistribution layer including more than one metal layer disposed in more than one passivation layer, the first set of bonding joints being directly coupled to at least one of the one or more metal layers, and a first set of connectors coupled to a second side of the redistribution layer, the second side being opposite the first side.

Embodiments of the present disclosure include semiconductor packages and methods of forming the same. An embodiment is a semiconductor package including a first package including one or more dies, and a redistribution layer coupled to the one or more dies at a first side of the first package with a first set of bonding joints. The redistribution layer including more than one metal layer disposed in more than one passivation layer, the first set of bonding joints being directly coupled to at least one of the one or more metal layers, and a first set of connectors coupled to a second side of the redistribution layer, the second side being opposite the first side.

A method of manufacturing an integrated fan-out (InFO) package includes at least the following steps. A package array is formed. A dielectric layer and a core material layer are sequentially formed on a first carrier. A portion of the core material layer is removed to form a core layer having a plurality of cavities. The first carrier, the dielectric layer, and the core layer are attached onto the package array such that the core layer is located between the dielectric layer and the package array. The first carrier is removed from the dielectric layer. A plurality of first conductive patches is formed on the dielectric layer above the cavities.

A method of making precise alignment and decal bonding of a pattern of solder preforms to a surface comprising cutting and placing a length of a solder ribbon onto a semiconductor release tape forming a solder ribbon and semiconductor release tape combination, placing the solder ribbon and semiconductor release tape combination on a vacuum chuck on X-Y stage pair in a laser micromachining system, adjusting the working distance, laser-cutting an outline, peeling off the solder ribbon, allowing the desired solder shape to remain, creating indexing holes, providing a target surface on an alignment fixture with indexing pins, aligning the indexing holes, placing the semiconductor release tape with the desired solder shape on the target surface, pressing the desired solder shape onto the target surface, removing the release tape, and making a pattern of the desired solder shape with precise alignment and decal bonding on the target surface.

This disclosure teaches methods for making high-temperature superconducting striated tape combinations and the product high-temperature superconducting striated tape combinations. This disclosure describes an efficient and scalable method for aligning and bonding two superimposed high-temperature superconducting (HTS) filamentary tapes to form a single integrated tape structure. This invention aligns a bottom and top HTS tape with a thin intervening insulator layer with microscopic precision, and electrically connects the two sets of tape filaments with each other. The insulating layer also reinforces adhesion of the top and bottom tapes, mitigating mechanical stress at the electrical connections. The ability of this method to precisely align separate tapes to form a single tape structure makes it compatible with a reel-to-reel production process.

A semiconductor device is provided comprising a support, an adhesive resin layer, an insulating layer, a redistribution layer, a chip layer, and a mold resin layer. The adhesive resin layer consists of a resin layer (A) comprising a photo-decomposable resin containing a fused ring in its main chain and a resin layer (B) comprising a non-silicone base thermoplastic resin and having a storage elastic modulus E of 1-500 MPa at 25 C. and a tensile break strength of 5-50 MPa. The semiconductor device is easy to fabricate and has thermal process resistance, the support is easily separated, and a semiconductor package is efficiently produced.

A semiconductor device includes: a first semiconductor structure including a stacked structure of a first dielectric layer and a first bonding dielectric layer; a second semiconductor structure including a stacked structure of a second dielectric layer and a second bonding dielectric layer; and a bonding pad penetrating the stacked structure of the first dielectric layer and the first bonding dielectric layer, and the stacked structure of the second dielectric layer and the second bonding dielectric layer, wherein the first bonding dielectric layer and the second bonding dielectric layer contact each other, and a first width of a first portion of the bonding pad penetrating the first dielectric layer is greater than each of a second width of a second portion of the bonding pad penetrating the first bonding dielectric layer, and a third width of a third portion of the bonding pad penetrating the second bonding dielectric layer.