There is provided a semiconductor device including: a pad portion that is provided above the upper surface of the semiconductor substrate and that is separated from the emitter electrode; a wire wiring portion that is connected to a connection region on an upper surface of the pad portion; a wiring layer that is provided between the semiconductor substrate and the pad portion and that includes a region overlapping the connection region; an interlayer dielectric film that is provided between the wiring layer and the pad portion and that has a through hole below the connection region; a tungsten portion that contains tungsten and that is provided inside the through hole and electrically connects the wiring layer and the pad portion; and a barrier metal layer that contains titanium and that is provided to cover an upper surface of the interlayer dielectric film below the connection region.

A semiconductor device includes first conductive films that are provided, above a semiconductor substrate, at least on both sides of a non-formation region in which the first conductive films are not provided; an interlayer dielectric film including a first portion that is provided on the non-formation region, second portions provided above the first conductive film on both sides of the non-formation region, and a step portion that connects the first portion and the second portions; a second conductive film provided above the interlayer dielectric film; through terminal portions that penetrate the second portions of the interlayer dielectric film; and a wire bonded with the second conductive film above the first portion, where the through terminal portions include one or more first through terminal portions and one or more second through terminal portions being provided at positions opposite to each other with a bonded portion of the wire being interposed therebetween.

In one embodiment, a semiconductor device includes a substrate, a lower pad provided above the substrate, and an upper pad provided on the lower pad. The lower pad includes a first pad and a plurality of first connection portions provided on the first pad, and the upper pad is provided on the plurality of first connection portions, or the upper pad includes a second pad and a plurality of second connection portions provided under the second pad, and the lower pad is provided under the plurality of second connection portions.

In an embodiment, a method for manufacturing and passivating a die includes providing the die having an active frontside including a protrusion, the protrusion configured for electrically contacting the die, covering a portion of the protrusion by a passivation tape before applying a passivation layer, applying the passivation layer on all sides of the die including the frontside and its protrusion in one single process, except on the portion covered by the passivation tape and detaching the passivation tape from the covered portion of the protrusion after applying the passivation layer to expose the portion of the protrusion which forms an electrical contact area.

A semiconductor device includes first and second metal-insulator-metal structures. The first metal-insulator-metal structure includes a first bottom conductor plate, a first portion of a first dielectric layer, a first middle conductor plate, a first portion of a second dielectric layer, and a first top conductor plate stacked up one over another. The second metal-insulator-metal structure includes a second bottom conductor plate, a second portion of the first dielectric layer, a second middle conductor plate, a second portion of the second dielectric layer, and a second top conductor plate stacked up one over another. In a cross-sectional view, the first bottom conductor plate is wider than the first middle conductor plate that is wider than the first top conductor plate, and the second bottom conductor plate is narrower than the second middle conductor plate that is narrower than the first top conductor plate.

A semiconductor device includes a substrate having a circuit region and a peripheral region disposed around and enclosing the circuit region in a plan view, a first interconnect layer formed on the substrate, a second interconnect layer formed on the first interconnect layer, a third interconnect layer formed on the second interconnect layer, and a guard ring formed in the peripheral region, wherein the guard ring includes a first interconnect formed in the first interconnect layer, and disposed around and enclosing the circuit region in a plan view, a second interconnect formed in the third interconnect layer, and disposed around and enclosing the circuit region in a plan view, and a first via connected to the first interconnect and to the second interconnect, and disposed in a groove shape along a perimeter edge of the substrate in a plan view.

The present disclosure provides a redistribution layer (RDL) structure, a semiconductor device and manufacturing method thereof. The semiconductor device comprising an RDL structure that may include a substrate, a first conductive layer, a reinforcement layer and, and a second conductive layer. The first conductive layer may be formed on the substrate and has a first bond pad area. The reinforcement layer may be formed on a surface of the first conductive layer facing away from the substrate and located in the first bond pad area. The second conductive layer may be formed on the reinforcement layer and an area of the first conductive layer not covered by the reinforcement layer. The reinforcement layer has a material strength greater than those of the first conductive layer and the second conductive layer.

Semiconductor apparatus and method for manufacturing semiconductor apparatus are provided. Semiconductor apparatus includes a semiconductor substrate having metal pads, a first passivation layer, a second passivation layer, an under bump metal layer, a stress buffer layer, a copper pillar and a solder structure. First passivation layer is formed on the semiconductor substrate and covers a portion of each metal pad, the first passivation layer has first passivation layer openings to expose a first portion of each metal pad. Second passivation layer is formed on the first passivation layer, the second passivation layer has second passivation layer openings to expose a second portion of each metal pad. Under bump metal layer is formed on the second portion of each metal pad exposed by the second passivation layer opening. Stress buffer layer is formed on the under bump metal layer, and the copper pillar is disposed on the stress buffer layer.

Methods and systems for double-sided semiconductor device fabrication. Devices having multiple leads on each surface can be fabricated using a high-temperature-resistant handle wafer and a medium-temperature-resistant handle wafer. Dopants can be introduced on both sides shortly before a single long high-temperature diffusion step diffuses all dopants to approximately equal depths on both sides. All high-temperature processing occurs with no handle wafer or with a high-temperature handle wafer attached. Once a medium-temperature handle wafer is attached, no high-temperature processing steps occur. High temperatures can be considered to be those which can result in damage to the device in the presence of aluminum-based metallizations.

A semiconductor package includes a first semiconductor chip including a first substrate and a first bonding layer disposed on the first substrate, and having a flat first outer surface provided by the first bonding layer; and a second semiconductor chip disposed on the first outer surface of the first semiconductor chip, including a second substrate and a second bonding layer disposed on the second substrate, and having a flat second outer surface provided by the second bonding layer and contacting the first outer surface of the first semiconductor chip. The first bonding layer includes a first outermost insulating layer providing the first outer surface, a first internal insulating layer stacked between the first outermost insulating layer and the first substrate, first external marks disposed in the first outermost insulating layer and spaced apart from each other, and first internal marks interlaced with the first external marks within the first internal insulating layer.