A conductive terminal on an integrated circuit is provided. The conductive terminal includes a conductive pad, a dielectric layer, and a conductive via. The conductive pad is disposed on and electrically to the integrated circuit. The dielectric layer covers the integrated circuit and the conductive pad, the dielectric layer includes a plurality of contact openings arranged in array, and the conductive pad is partially exposed by the contact openings. The conductive via is disposed on the dielectric layer and electrically connected to the conductive pad through the contact openings. The conductive via includes a plurality of convex portions arranged in array. The convex portions are distributed on a top surface of the conductive via, and the convex portions are corresponding to the contact openings.

A method of fabricating an under-bump metallurgy (UBM) structure that is free of gold processing includes forming a titanium layer on top of a far back of line (FBEOL) of a semiconductor. A first copper layer is formed on top of the titanium layer. A photoresist (PR) layer is formed on top of the first copper layer between traces of the FBEOL to provide a cavity to the FBEOL traces. A top copper layer is formed on top of the first copper layer. A protective surface layer (PSL) is formed on top of the top copper layer.

Provided is a method for manufacturing a semiconductor device that improves the reliability of the semiconductor device under thermal stress and the assembly performance of the semiconductor device in manufacturing steps. The method includes the following: forming a first electrode by depositing a first conductive film onto one main surface of a semiconductor substrate and patterning the first conductive film; forming a first metal film corresponding to a pattern of the first electrode onto the first electrode; forming a second electrode by depositing a second conductive film onto the other main surface of the semiconductor substrate; forming a second metal film thinner than the first metal film onto the second electrode; and collectively forming a third metal film onto each of the first metal film and the second metal film by electroless plating.

A semiconductor device includes a semiconductor die. The semiconductor die includes a device layer, an interconnect layer over the device layer, a conductive pad over the interconnect layer, a conductive seed layer directly on the conductive pad, and a passivation layer encapsulating the conductive pad and the conductive seed layer. The conductive pad is between the interconnect layer and the conductive seed layer.

A solder connection may be surrounded by a solder locking layer (1210, 2210) and may be recessed in a hole (1230) in that layer. The recess may be obtained by evaporating a vaporizable portion (1250) of the solder connection. Other features are also provided.

Semiconductor devices, integrated circuits and methods of forming the same are provided. In one embodiment, a method includes depositing a first dielectric layer over a metal pad disposed over a workpiece, forming a first opening in the first dielectric layer to expose a portion of the metal pad, after the forming of the first opening, forming a second dielectric layer over the exposed portion of the metal pad, depositing a first polymeric material over the second dielectric layer, forming a second opening through the first polymeric material and the second dielectric layer to expose the metal pad, and forming a bump feature over the exposed metal pad.

A design structure for an integrated radio frequency (RF) filter on a backside of a semiconductor substrate includes: a device on a first side of a substrate; a radio frequency (RF) filter on a backside of the substrate; and at least one substrate conductor extending from the front side of the substrate to the backside of the substrate and electrically coupling the RF filter to the device.

Representative techniques provide process steps for forming a microelectronic assembly, including preparing microelectronic components such as dies, wafers, substrates, and the like, for bonding. One or more surfaces of the microelectronic components are formed and prepared as bonding surfaces. The microelectronic components are stacked and bonded without adhesive at the prepared bonding surfaces.

Representative techniques provide process steps for forming a microelectronic assembly, including preparing microelectronic components such as dies, wafers, substrates, and the like, for bonding. One or more surfaces of the microelectronic components are formed and prepared as bonding surfaces. The microelectronic components are stacked and bonded without adhesive at the prepared bonding surfaces.

The present disclosure discloses a semiconductor device structure with an air gap for reducing capacitive coupling and a method for forming the semiconductor device structure. The semiconductor device structure includes a first conductive pad over a first semiconductor substrate, and a first conductive structure over the first conductive pad. The semiconductor device structure also includes a second conductive structure over the first conductive structure, and a second conductive pad over the second conductive structure. The second conductive pad is electrically connected to the first conductive pad through the first and the second conductive structures. The semiconductor device structure further includes a second semiconductor substrate over the second conductive pad, a first passivation layer between the first and the second semiconductor substrates and covering the first conductive structure, and a second passivation layer between the first passivation layer and the second semiconductor substrate. The first and the second passivation layers surround the second conductive structure, and a first air gap is enclosed by the first and the second passivation layers.