An improvement is achieved in the performance of a semiconductor-device. The semiconductor device includes MISFETs formed in the upper surface of a substrate, a plurality of wiring layers stacked over the upper surface of the substrate, and a plurality of plugs each coupling two of the wiring layers to each other. The wiring layers located under the uppermost wiring layer include wires. The uppermost wiring layer includes a pad, an insulating film formed over the pad, and an opening extending through the insulating film and reaching the pad. The MISFETs and the wires overlap the opening in plan view. None of the plurality of plugs overlaps the opening in plan view.

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.

Structures and formation methods of a chip package are provided. The chip package includes a semiconductor die having a conductive element and a first protective layer surrounding the semiconductor die. The chip package also includes a second protective layer over the semiconductor die and the first protective layer. The chip package further includes an antenna element over the second protective layer. The antenna element is electrically connected to the conductive element of the semiconductor die.

A semiconductor device includes a bonding pad that includes a base portion having a base layer. A bond wire or clip is bonded to a bonding region of a main surface of the bonding pad. A supplemental structure is in direct contact with the base portion next to the bonding region. A specific heat capacity of the supplemental structure is higher than a specific heat capacity of the base layer.

A device-bonded body includes: a first device where a plated bump is disposed; a second device where a bonding electrode bonded to the plated bump is disposed; and a sealing layer made of NCF or NCP, the sealing layer being disposed between the first device and the second device and including filler particles made of inorganic material; wherein a surface of the plated bump includes a first area and a second area higher than the first area; and at least a part of a side surface of an outer circumferential portion of the second area intersects with a surface of the first area.

To provide a semiconductor device that prevents a surface of a bonding pad from being made rough and can also reduce dimensions of the bonding pad, a semiconductor device according to an embodiment includes a bonding pad containing aluminum, a titanium nitride film, a passivation film, and a sidewall protection film including a first layer and a second layer. An opening is provided in the titanium nitride film and the passivation film. The opening includes a sidewall and exposes the bonding pad therethrough. The first layer of the sidewall protection film covers at least the titanium nitride film over the sidewall, and the second layer covers the first layer. A material forming the first layer and a material forming the second layer are different from each other in an etching rate in etching under the same condition.

A semiconductor device includes a substrate having a cell region and a circuit region, an upper wiring layer on the substrate, and a redistribution wiring layer on the upper wiring layer. The upper wiring layer includes a secondary uppermost wiring in the circuit region and an uppermost wiring on the secondary uppermost wiring. The uppermost wiring includes an uppermost chip pad electrically connected to the secondary uppermost wiring. At least a portion of the uppermost chip pad in the cell region. The redistribution wiring layer includes a redistribution wiring electrically connected to the uppermost chip pad. At least a portion of the redistribution wiring serving as a landing pad connected to an external connector.

A fan-out semiconductor package includes a first core member including a first through-hole, a first semiconductor chip disposed in the first through-hole of the first core member, a first encapsulant configured to encapsulate at least a portion of the first semiconductor chip, a first connection member disposed on the first semiconductor chip and including a first redistribution layer, a second core member adhered to a lower surface of the first connection member and including a second through-hole, a second semiconductor chip disposed in the second through-hole of the second core member, a second encapsulant configured to encapsulate the second semiconductor chip, the second core member, and the first connection member, a second connection member disposed on the second semiconductor chip and including a second redistribution layer, and a connection via penetrating through the second core member and configured to electrically connect the first redistribution layer and the second redistribution layer.

In some examples, a device includes a first conductive region and a second conductive region that is galvanically isolated from the first conductive region. The device further includes one or more conductors, wherein each conductor of the one or more conductors is electrically connected to circuitry in the first conductive region. The device also includes a giant magnetoresistive (GMR) sensor electrically connected to circuitry in the second conductive region and magnetically coupled to the one or more conductors, wherein the GMR sensor is positioned at least partially lateral relative to the one or more conductors.

A method of fabricating a contact hole and a fuse hole includes providing a dielectric layer. A conductive pad and a fuse are disposed within the dielectric layer. Then, a first mask is formed to cover the dielectric layer. Later, a first removing process is performed by taking the first mask as a mask to remove part the dielectric layer to form a first trench. The conductive pad is disposed directly under the first trench and does not expose through the first trench. Subsequently, the first mask is removed. After that, a second mask is formed to cover the dielectric layer. Then, a second removing process is performed to remove the dielectric layer directly under the first trench to form a contact hole and to remove the dielectric layer directly above the fuse by taking the second mask as a mask to form a fuse hole.