A method of forming an aluminum oxide layer is provided. The method includes providing a metal surface including at least one metal of a group of metals, the group of metals consisting of copper, aluminum, palladium, nickel, silver, and alloys thereof. The method further includes depositing an aluminum oxide layer on the metal surface by atomic layer deposition, wherein a maximum processing temperature during the depositing is 280° C., such that the aluminum oxide layer is formed with a surface having a liquid solder contact angle of less than 40°.

Provided is a solid-state imaging device that suppresses propagation of a crack. There is provided a solid-state imaging device including: a first substrate on which a pixel unit configured to perform photoelectric conversion is formed; and a second substrate on which a logic circuit configured to process a pixel signal outputted from the pixel unit is formed, in which the first and second substrates are laminated by being connected by metal binding between wiring layers that are formed individually, an opening hole is formed on an outer periphery of the pixel unit to penetrate the first and second substrates to reach an upper part of a wire bonding pad formed in the second substrate, the second substrate includes an insulating layer below the wire bonding pad, and the insulating layer includes a first insulating film.

A package includes an integrated circuit that includes at least one active area and at least one secondary device area, a support configured to support the integrated circuit, and a die attach material. The integrated circuit being mounted on the support using the die attach material and the die attach material including at least one channel configured to allow gases generated during curing of the die attach material to be released from the die attach material.

There is provided a semiconductor device including: a plurality of bumps on a first semiconductor substrate; and a lens material in a region other than the plurality of bumps on the first semiconductor substrate, wherein a distance between a side of a bump closest to the lens material and a side of the lens material closest to the bump is greater than twice a diameter of the bump closest to the lens material, and wherein the distance between the side of the bump closest to the lens material and the side of the lens material closest to the bump is greater a minimum pitch of the bumps.

A light emitting device filament includes a substrate, a plurality of light emitting diodes, two electrode pads, and a plurality of connection lines. The substrate includes a first surface and a second surface opposite to the first surface. The substrate extending in a first direction and having a width in a second direction. The plurality of light emitting diodes is disposed on the first surface of the substrate. The two electrode pads are disposed on the substrate. The plurality of connection lines electrically connects the plurality of light emitting diodes and the two electrode pads. The plurality of connection lines includes a first connection line and a second connection line. The first connection line, the second connection line, or both are formed in a direction inclined or curved with respect to the first direction or the second direction.

In an embodiment, a semiconductor device includes a galvanically isolated signal transfer coupler having a contact pad. The contact pad includes a metallic base layer, a metallic diffusion barrier layer arranged on the metallic base layer, and a metallic wire bondable layer arranged on the metallic diffusion barrier layer. The metallic diffusion barrier layer includes a first portion and a second portion. The first portion has a first surface and a second surface opposing the first surface. The first surface has a curved surface at the periphery. The first portion extends in a transverse plane and has a width. The second portion protrudes from the second surface intermediate the width of the first portion.

A bonding pad layer system is deposited on a semiconductor chip as a base, for example, a micromechanical semiconductor chip, in which at least one self-supporting dielectric membrane made up of dielectric layers, a platinum conductor track and a heater made of platinum is integrated. In the process, the deposition of a tantalum layer takes place first, upon that the deposition of a first platinum layer, upon that the deposition of a tantalum nitride layer, upon that the deposition of a second platinum layer and upon that the deposition of a gold layer, at least one bonding pad for connecting with a bonding wire being formed in the gold layer. The bonding pad is situated in the area of the contact hole on the semiconductor chip, in which a platinum conductor track leading to the heater is connected using a ring contact and/or is connected outside this area.

A dielectric film is disposed on a semiconductor substrate, and a conductor including a bent section is arranged between the semiconductor substrate and the dielectric film. A pad is disposed on the dielectric film. The pad is covered with a protective film. The protective film has an opening through which an upper surface of the pad is exposed. The bent section in the conductor and the pad overlap each other as seen in plan view, and an inside corner and an outside corner in the bent section are chamfered.

To arrange a protective material horizontally with respect to a substrate plane without the protective material coming into contact with wires in a wire-bonded semiconductor package.

The semiconductor package includes a protective material, a substrate, bumps, and a semiconductor chip. The bumps are provided on a chip plane of the semiconductor chip and are connected to the substrate via wires. The semiconductor chip is laminated on the substrate. A support is provided on the chip plane to support the protective material at a position where the height from the chip plane of the semiconductor chip is higher than the bumps.

Damage to a semiconductor device at the time of forming a via hole in which a through electrode is arranged is prevented. The semiconductor device includes a cylindrical insulating film, a front surface side pad, a conductor layer, and a back surface side pad. The cylindrical insulating film is configured in a cylindrical shape penetrating a semiconductor substrate. The front surface side pad is formed adjacent to a front surface of the semiconductor substrate inside the cylindrical insulating film. The conductor layer is arranged adjacent to the front surface side pad and an inner side of the cylindrical insulating film after removing the semiconductor substrate inside the cylindrical insulating film adjacent to the front surface side pad. The back surface side pad is arranged on a back surface of the semiconductor substrate and is connected to the front surface side pad via the conductor layer.