A power semiconductor device including a first and second die, each including a plurality of conductive contact regions and a passivation region including a number of projecting dielectric regions and a number of windows. Adjacent windows are separated by a corresponding projecting dielectric region with each conductive contact region arranged within a corresponding window. A package of the surface mount type houses the first and second dice. The package includes a first bottom insulation multilayer and a second bottom insulation multilayer carrying, respectively, the first and second dice. A covering metal layer is arranged on top of the first and second dice and includes projecting metal regions extending into the windows to couple electrically with corresponding conductive contact regions. The covering metal layer moreover forms a number of cavities, which are interposed between the projecting metal regions so as to overlie corresponding projecting dielectric regions.

A copper pillar bump structure on a copper pillar on a metal pad of a semiconductor device and a method of fabricating thereof are disclosed. The copper pillar bump structure includes: a metal barrier layer formed on the copper pillar. The metal barrier layer has a U-shaped cross section, a central portion of the metal barrier layer covers the top surface of the copper pillar, an opening of the U-shaped cross section faces away from the copper pillar. The copper pillar bump structure further includes a solder layer on the copper pillar and filling the U-shaped cross section. The copper pillar bump structure provides a metal barrier layer having a U-shaped cross section and fills a solder layer in the U-shaped cross section, the metal barrier layer wraps sides of the solder layer, which can improve the non-wetting problem caused by insufficient tin, or the solder bridging problem caused by excessive solder, during a flip die soldering process.

A semiconductor structure is disclosed. The semiconductor structure includes: a polymer base layer; a backside redistribution layer (RDL) over the polymer base layer; a molding layer over the backside RDL; a polymer layer over the molding layer; a front side RDL over the polymer layer; and a metal-insulator-metal (MIM) capacitor vertically passing through the molding layer, the MIM capacitor including a first electrode, an insulation layer and a second electrode, wherein the insulation layer surrounds the first electrode, and the second electrode surrounds the insulation layer, and the molding layer surrounds the second electrode. An associated method for manufacturing a semiconductor structure is also disclosed.

A semiconductor element includes an element body, a surface protective film and an electrode. The element body has a front surface and a side surface connected to the front surface. The surface protective film is supported on the front surface of the element body. The surface protective film has a cutout portion recessed inward from an outer edge of the surface protective film as viewed in a thickness direction of the element body. The electrode is disposed in the cutout portion and electrically connected to the element body. The element body has a ledge protruding with respect to the side surface in a direction perpendicular to the thickness direction. The ledge is adjacent to an opening of the cutout portion as viewed in the thickness direction.

A thermal compression flip chip (TCFC) bump may be used for high performance products that benefit from a fine pitch. In one example, a new TCFC bump structure adds a metal pad underneath the TCFC copper pillar bump to cover the exposed aluminum bump pad. This new structure prevents the pad from corroding and reduces mechanical stress to the pad and underlying silicon dielectric layers enabling better quality and reliability and further bump size reduction. For example, a flip chip connection may include a substrate; a metal pad on a contact side of the substrate and a first passivation layer on the contact side of the substrate to protect the metal pad from corrosion.

A semiconductor package and a fabrication method of the semiconductor package are disclosed. First and second redistribution layer patterns are formed on a semiconductor substrate including a chip region and a scribe lane region to provide a bonding pad portion and an edge pad portion, respectively. A polymer pattern is formed to reveal the bonding pad portion and a portion of the edge pad portion. A dicing line is set on the scribe lane region. A stealth dicing process is performed along the dicing line to separate a semiconductor chip including the bonding pad portion from the semiconductor substrate. The semiconductor chip is disposed on a package substrate. A bonding wire is formed to connect the bonding pad portion to the package substrate. The bonding wire is supported by an edge of the polymer pattern to be spaced apart from the revealed portion of the edge pad portion.

According to one embodiment, a semiconductor device includes a first electrode, a second electrode, and a wire extending between the first electrode and the second electrode. The wire includes a first conductor in contact with the first electrode and the second electrode, and a second conductor that is provided inside the first conductor and has no contact with the first electrode and the second electrode.

A package and method of making a package is disclosed. In one example, the package includes an electronic chip having at least one pad, an encapsulant at least partially encapsulating the electronic chip, and an electrically conductive contact element extending from the at least one pad and through the encapsulant so as to be exposed with respect to the encapsulant. The electrically conductive contact element comprises a first contact structure made of a first electrically conductive material on the at least one pad and comprises a second contact structure made of a second electrically conductive material and being exposed with respect to the encapsulant. At least one of the at least one pad has at least a surface portion which comprises or is made of the first electrically conductive material.

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.

In a semiconductor device, a first protection film covers an end portion of a first metal layer disposed on a semiconductor substrate, and has a first opening above the first metal layer. A second metal layer is disposed on the first metal layer in the first opening. An oxidation inhibition layer is disposed on the second metal layer in the first opening. A second protection film has a second opening and covers an end portion of the oxidation inhibition layer and the first protection film. The second protection film has an opening peripheral portion on a periphery of the second opening, and covers the end portion of the oxidation inhibition layer. An adhesion portion adheres to a portion of a lower surface of the opening peripheral portion. The adhesion portion has a higher adhesive strength with the second protection film than the oxidation inhibition layer.