Techniques are employed to mitigate the anchoring effects of cavity sidewall adhesion on an embedded conductive interconnect structure, and to allow a lower annealing temperature to be used to join opposing conductive interconnect structures. A vertical gap may be disposed between the conductive material of an embedded interconnect structure and the sidewall of the cavity to laterally unpin the conductive structure and allow uniaxial expansion of the conductive material. Additionally or alternatively, one or more vertical gaps may be disposed within the bonding layer, near the embedded interconnect structure to laterally unpin the conductive structure and allow uniaxial expansion of the conductive material.

A semiconductor device includes at least one base element, at least one passivation layer, at least one circuit layer and at least one light absorbing layer. The base element includes at least one conductive pad. The passivation layer is disposed on the base element. The circuit layer is electrically connected to the conductive pad and disposed in the passivation layer. The light absorbing layer is disposed on the circuit layer.

To provide a semiconductor device having improved reliability. A method of manufacturing the semiconductor device includes connecting a wire comprised of copper with a conductive layer formed on the pad electrode of a semiconductor chip, heat treating the semiconductor chip, and then sealing the semiconductor chip and the wire with a resin.

A semiconductor structure, a method for forming a semiconductor structure, a stacked structure, and a wafer stacking method are provided. The semiconductor structure includes: a semiconductor substrate; a first dielectric layer on a surface of a semiconductor substrate; a top metal layer, in which the top metal layer is located in the first dielectric layer, and the top metal layer penetrates through the first dielectric layer; and a buffer layer located between the top metal layer and the first dielectric layer.

The present technology is directed to manufacturing semiconductor dies with under-bump metal (UBM) structures for die-to-die and/or package-to-package interconnects or other types of interconnects. In one embodiment, a method for forming under-bump metal (UBM) structures on a semiconductor die comprises constructing a UBM pillar by plating a first material onto first areas of a seed structure and depositing a second material over the first material. The first material has first electrical potential and the second material has a second electrical potential greater than the first electrical potential. The method further comprises reducing the difference in the electrical potential between the first material and the second material, and then removing second areas of the seed structure between the UBM pillars thereby forming UBM structures on the semiconductor die.

A semiconductor device and a semiconductor package, the device including a first buffer dielectric layer on a first dielectric layer; a second dielectric layer and a second buffer dielectric layer sequentially disposed on the first buffer dielectric layer, the second buffer dielectric layer being in contact with the first buffer dielectric layer; and a pad interconnection structure that penetrates the first buffer dielectric layer and the second buffer dielectric layer, wherein the pad interconnection structure includes copper and tin.

A film-type semiconductor package includes a metal lead portion arranged on a film substrate, a semiconductor chip including a pad, and a bump connecting the metal lead portion to the pad of the semiconductor chip. The bump includes a metal pillar arranged on the pad and including a first metal and a soldering portion arranged on an entire surface of the metal pillar, bonded to the metal lead portion, and including the first metal and a second metal that is different from the first metal.

A semiconductor device includes a plurality of semiconductor die and a plurality of conductive vias formed in the semiconductor die. An insulating layer is formed over the semiconductor die while leaving the conductive vias exposed. An interconnect structure is formed over the insulating layer and conductive vias. The insulating layer is formed using electrografting or oxidation. An under bump metallization is formed over the conductive vias. A portion of the semiconductor die is removed to expose the conductive vias. The interconnect structure is formed over two or more of the conductive vias. A portion of the semiconductor die is removed to leave the conductive vias with a height greater than a height of the semiconductor die. A second insulating layer is formed over the first insulating layer. A portion of the second insulating layer is removed to expose the conductive via.

A nitride semiconductor module includes a chip including at least one transistor, wherein the chip includes: a semiconductor substrate including a substrate upper surface and a substrate lower surface facing an opposite side of the substrate upper surface; an electron transit layer formed over the substrate upper surface of the semiconductor substrate and made of GaN; and an electron supply layer formed over the electron transit layer and made of GaN having a larger band gap than the electron transit layer, wherein the at least one transistor includes a gate electrode, a source electrode, and a drain electrode, which are formed over the electron supply layer, and wherein the semiconductor substrate is a GaN substrate having a thickness of 100 m or less.

A semiconductor device and a semiconductor package, the device including a first buffer dielectric layer on a first dielectric layer; a second dielectric layer and a second buffer dielectric layer sequentially disposed on the first buffer dielectric layer, the second buffer dielectric layer being in contact with the first buffer dielectric layer; and a pad interconnection structure that penetrates the first buffer dielectric layer and the second buffer dielectric layer, wherein the pad interconnection structure includes copper and tin.