A semiconductor apparatus includes elements formed on a substrate, a first insulation layer, a first pad and a second pad arranged on the first insulation layer and located above the elements, and a second insulation layer that is arranged on the side surfaces and upper surfaces of the first pad and the second pad. The second insulation layer includes openings at upper surfaces of the first pad and the second pad. The thickness of the first pad and the second pad is 2 m or more, the thickness of the second insulation layer is less than or equal to of the thickness of the first pad and the second pad, and the distance between the first pad and the second pad is greater than or equal to four times the thickness of the first pad and the second pad.

The present technology is directed to manufacturing collars for under-bump metal (UBM) structures for die-to-die and/or package-to-package interconnects and associated systems. A semiconductor die includes a semiconductor material having solid-state components and an interconnect extending at least partially through the semiconductor material. An under-bump metal (UBM) structure is formed over the semiconductor material and is electrically coupled to corresponding interconnects. A collar surrounds at least a portion of the side surface of the UBM structure, and a solder material is disposed over the top surface of the UBM structure.

Provided is a semiconductor device with improved reliability that achieves the reduction in size. A semiconductor wafer is provided that has a first insulating member with an opening that exposes from which an upper surface of an electrode pad. Subsequently, after forming a second insulating member over a main surface of the semiconductor wafer, another opening is formed to expose the upper surface of the electrode pad. Then, a probe needle is brought into contact with the electrode pad, to write data in a memory circuit at the main surface of the semiconductor wafer. After covering the upper surface of the electrode pad with a conductive cover film, a relocation wiring is formed. In the Y direction, the width of the relocation wiring positioned directly above the electrode pad is equal to or smaller than the width of the opening formed in the first insulating member.

A chip package includes a chip, a dam layer, a permanent adhesive layer, a support, a buffer layer, a redistribution layer, a passivation layer, and a conducting structure. A conducting pad and a sensing device of the chip are located on a first surface of a substrate of the chip, and the conducting pad protrudes from the side surface of the substrate. The dam layer surrounds the sensing device. The permanent adhesive layer is between the support and the substrate. The support and the permanent adhesive layer have a trench to expose the conducting pad. The buffer layer is located on the support. The redistribution layer is located on the buffer layer and on the support, the permanent adhesive layer, and the conducting pad facing the trench. The passivation layer covers the redistribution layer, the buffer layer, and the conducting pad.

A chip part includes a substrate, an element formed on the substrate, and an electrode formed on the substrate. A recess and/or projection expressing information related to the element is formed at a peripheral edge portion of the substrate.

An electronic device includes an electronic element, and a wire bonded to the electronic element. The electronic element includes a bonding pad to which the wire is bonded. The main component of the bonding pad is Al. A metal is mixed in the wire, and the mixed metal is one of Pt, Pd and Au.

The embodiments described provide elongated bonded structures near edges of packaged structures free of solder wetting on sides of copper posts substantially facing the center of the packaged structures. Solder wetting occurs on other sides of copper posts of these bonded structures. The elongated bonded structures are arranged in different arrangements and reduce the chance of shorting between neighboring bonded structures. In addition, the elongated bonded structures improve the reliability performance.

A stacked semiconductor device structure includes a first semiconductor device having a first major surface and a second major surface opposite to the first major surface. The second major surface includes a recessed region bounded by sidewall portions, and the sidewall portions have outer surfaces defining peripheral edge segments of the first semiconductor device. A first conductive layer is disposed adjoining at least portions of the recessed region. A second semiconductor device having a third major surface and a fourth major surface opposite to the third major surface includes a first portion that is electrically connected to the first conductive layer within the recessed region, and at least a portion of the second semiconductor device is disposed within the recessed region.

An integrated circuit and method comprising an underlying metal geometry, a dielectric layer on the underlying metal geometry, a contact opening through the dielectric layer, an overlying metal geometry wherein a portion of the overlying metal geometry fills a portion of the contact opening, and an oxidation resistant barrier layer disposed between the underlying metal geometry and overlying metal geometry. The oxidation resistant barrier layer is formed of TaN or TiN with a nitrogen content of at least 20 atomic % and a thickness of at least 5 nm.

Methods of fabricating semiconductor packages are provided. One of the methods includes forming a protection layer including metal on a first surface of a substrate to cover a semiconductor device disposed on the first surface of the substrate, attaching a support substrate to the protection layer by using an adhesive member, processing a second surface of the substrate opposite to the protection layer to remove a part of the substrate, and detaching the support substrate from the substrate.