In a method of manufacturing a semiconductor device first conductive layers are formed over a substrate. A first photoresist layer is formed over the first conductive layers. The first conductive layers are etched by using the first photoresist layer as an etching mask, to form an island pattern of the first conductive layers separated from a bus bar pattern of the first conductive layers by a ring shape groove. A connection pattern is formed to connect the island pattern and the bus bar pattern. A second photoresist layer is formed over the first conductive layers and the connection pattern. The second photoresist layer includes an opening over the island pattern. Second conductive layers are formed on the island pattern in the opening. The second photoresist layer is removed, and the connection pattern is removed, thereby forming a bump structure.

During electro-oxidative metal removal on a semiconductor substrate, the substrate having a metal layer is anodically biased and the metal is electrochemically dissolved into an electrolyte. Metal particles (e.g., copper particles when the dissolved metal is copper) can inadvertently form on the surface of the substrate during electrochemical metal removal and cause defects during subsequent semiconductor processing. Contamination with such particles can be mitigated by preventing particle formation and/or by dissolution of particles. In one implementation, mitigation involves using an electrolyte that includes an oxidizer, such as hydrogen peroxide, during the electrochemical metal removal. An electrochemical metal removal apparatus in one embodiment has a conduit for introducing an oxidizer to the electrolyte and a sensor for monitoring the concentration of the oxidizer in the electrolyte.

During electro-oxidative metal removal on a semiconductor substrate, the substrate having a metal layer is anodically biased and the metal is electrochemically dissolved into an electrolyte. Metal particles (e.g., copper particles when the dissolved metal is copper) can inadvertently form on the surface of the substrate during electrochemical metal removal and cause defects during subsequent semiconductor processing. Contamination with such particles can be mitigated by preventing particle formation and/or by dissolution of particles. In one implementation, mitigation involves using an electrolyte that includes an oxidizer, such as hydrogen peroxide, during the electrochemical metal removal. An electrochemical metal removal apparatus in one embodiment has a conduit for introducing an oxidizer to the electrolyte and a sensor for monitoring the concentration of the oxidizer in the electrolyte.

A semiconductor device such as a chip-scale package is provided. Aspects of the present disclosure further relate to a method for manufacturing such a device. According to an aspect of the present disclosure, a semiconductor device is provided that includes a conformal coating arranged on its sidewalls and on the perimeter part of the semiconductor die of the semiconductor device. To prevent the conformal coating from covering unwanted areas, such as electrical terminals, a sacrificial layer is arranged prior to arranging the conformal coating. By removing the sacrificial layer, the conformal coating can be removed locally. The conformal coating covers the perimeter part of the semiconductor die by the semiconductor device, in which part a remainder of a sawing line or dicing street is provided.

Electronic device package technology is disclosed. In one example, an electronic device comprises a die (18) having a bond pad (22); and a decoupling capacitor (14) mounted on the die (18) and electrically coupled to the die (18). A method for making an electronic device comprises mounting a decoupling capacitor (14) on a die (18); and electrically coupling the decoupling capacitor (14) to the die (18).

Electronic device package technology is disclosed. In one example, an electronic device comprises a die (18) having a bond pad (22); and a decoupling capacitor (14) mounted on the die (18) and electrically coupled to the die (18). A method for making an electronic device comprises mounting a decoupling capacitor (14) on a die (18); and electrically coupling the decoupling capacitor (14) to the die (18).

In one example, an electronic device comprises a base substrate comprising a base substrate conductive structure, a first electronic component over a first side of the base substrate, an encapsulant over the first side of the base substrate, wherein the encapsulant contacts a lateral side of the electronic component, an interposer substrate over a first side of the encapsulant and comprising an interposer substrate conductive structure, and a vertical interconnect in the encapsulant and coupled with the base substrate conductive structure and the interposer substrate conductive structure. A first one of the base substrate or the interposer substrate comprises a redistribution layer (RDL) substrate, and a second one of the base substrate or the interposer substrate comprises a laminate substrate. Other examples and related methods are also disclosed herein.

In one example, an electronic device comprises a base substrate comprising a base substrate conductive structure, a first electronic component over a first side of the base substrate, an encapsulant over the first side of the base substrate, wherein the encapsulant contacts a lateral side of the electronic component, an interposer substrate over a first side of the encapsulant and comprising an interposer substrate conductive structure, and a vertical interconnect in the encapsulant and coupled with the base substrate conductive structure and the interposer substrate conductive structure. A first one of the base substrate or the interposer substrate comprises a redistribution layer (RDL) substrate, and a second one of the base substrate or the interposer substrate comprises a laminate substrate. Other examples and related methods are also disclosed herein.

Embodiments include semiconductor packages and methods to form the semiconductor packages. A semiconductor package includes a plurality of first dies on a substrate, an interface layer over the first dies, a backside metallization (BSM) layer directly on the interface layer, where the BSM layer includes first, second, and third conductive layer, and a heat spreader over the BSM layer. The first conductive layer includes a titanium material. The second conductive layer includes a nickel-vanadium material. The third conductive layer includes a gold material, a silver material, or a copper material. The copper material may include copper bumps. The semiconductor package may include a plurality of second dies on a package substrate. The substrate may be on the package substrate. The second dies may have top surfaces substantially coplanar to top surface of the first dies. The BSM and interface layers may be respectively over the first and second dies.

Embodiments include semiconductor packages and methods to form the semiconductor packages. A semiconductor package includes a plurality of first dies on a substrate, an interface layer over the first dies, a backside metallization (BSM) layer directly on the interface layer, where the BSM layer includes first, second, and third conductive layer, and a heat spreader over the BSM layer. The first conductive layer includes a titanium material. The second conductive layer includes a nickel-vanadium material. The third conductive layer includes a gold material, a silver material, or a copper material. The copper material may include copper bumps. The semiconductor package may include a plurality of second dies on a package substrate. The substrate may be on the package substrate. The second dies may have top surfaces substantially coplanar to top surface of the first dies. The BSM and interface layers may be respectively over the first and second dies.