There is provided semiconductor devices and methods of forming the same, the semiconductor devices including: a first semiconductor element having a first electrode; a second semiconductor element having a second electrode; a Sn-based micro-solder bump formed on the second electrode; and a concave bump pad including the first electrode opposite to the micro-solder bump, where the first electrode is connected to the second electrode via the micro-solder bump and the concave bump pad.

An integrated circuit (IC) comprising an enhanced passivation scheme for pad openings and trenches is provided. In some embodiments, an interlayer dielectric (ILD) layer covers a substrate and at least partially defines a trench. The trench extends through the ILD layer from a top of the ILD layer to the substrate. A conductive pad overlies the ILD layer. A first passivation layer overlies the ILD layer and the conductive pad, and further defines a pad opening overlying the conductive pad. A second passivation layer overlies the ILD layer, the conductive pad, and the first passivation layer, and further lines sidewalls of the first passivation layer in the pad opening and sidewalls of the ILD layer in the trench. Further, the second passivation layer has a low permeability for moisture or vapor relative to the ILD layer.

The present invention relates to a semiconductor structure and method of forming the same. The semiconductor structure includes a first substrate and a first bonding layer on a surface of the first substrate, and the material of first bonding layer includes dielectric materials of silicon, nitrogen and carbon, and an atomic concentration of carbon in the first bonding layer gradually increases along with an increase of thickness of the first bonding layer from the surface of first substrate and reaches a maximum atomic concentration of carbon at a surface of the first bonding layer.

A semiconductor device includes a first passivation layer over a circuit and. conductive pad over the first passivation layer, wherein the conductive pad is electrically connected to the circuit. A second passivation layer is disposed over the conductive pad and the first passivation layer, and has a first opening and a second opening. The first opening exposes an upper surface of a layer that extends underneath the conductive pad, and the second opening exposes the conductive pad. A first insulating layer is disposed over the second passivation layer and filling the first and second openings. A through substrate via extends through the insulating layer, second passivation layer, passivation layer, and substrate. A side of the through substrate via and the second passivation layer have a gap that is filled with the first insulating layer. A conductive via extends through the first insulating layer and connecting to the conductive pad.

A method of manufacturing a redistribution layer includes: forming an insulating layer on a wafer, delimited by a top surface and a bottom surface in contact with the wafer; forming a conductive body above the top surface of the insulating layer; forming a first coating region extending around and above the conductive body, in contact with the conductive body, and in contact with the top surface of the insulating layer in correspondence of a bottom surface of the first coating region; applying a thermal treatment to the wafer in order to modify a residual stress of the first coating region, forming a gap between the bottom surface of the first coating region and the top surface of the insulating layer; forming, after applying the thermal treatment, a second coating region extending around and above the first coating region, filling said gap and completely sealing the first coating region.

A semiconductor chip includes a front surface and a back surface, a source pad, a drain pad and a gate pad on the front surface; a die pad under the semiconductor chip and bonded to the semiconductor chip; a source lead, electrically connected to the die pad; a drain lead and a gate lead, disposed on a periphery of the die pad; and a sealing resin. A plurality of vias for external connection are formed to connect to the source pad. A first subset of the plurality of vias for external connection is disposed along a first side of the source pad, and a second subset of the plurality of vias for external connection is disposed along a second side of the source pad, wherein the first and second sides are arranged adjacent to each other to form a first edge of the source pad.

Some embodiments include apparatuses and methods of fabricating the apparatuses. One of the apparatuses includes a substrate of a semiconductor die; a memory cell portion located over a first portion of the substrate; a conductive pad portion located over a second portion of the substrate and outside the memory cell portion; and a sensor circuit including a portion located over the second portion of the substrate and under the conductive pad portion. The conductive pad portion includes conductive pads. Each of the conductive pads is part of a respective electrical path coupled to a conductive contact of a base outside the substrate.

A fingerprint recognition module according to an embodiment includes a substrate; a conductive pattern portion disposed on the substrate; a protective layer partially disposed on the substrate and the conductive pattern portion; a first connection portion disposed on a conductive pattern portion exposed through a first open region of the protective layer; and a first chip disposed on the first connection portion; wherein the first connection portion includes an anisotropic conductive adhesive disposed on the conductive pattern portion exposed through the first open region and having a closed loop shape and including conductive particles.

An interposer comprises a semiconductor material and includes cache memory under a location on the interposer for a host device. Memory interface circuitry may also be located under one or more locations on the interposer for memory devices. Microelectronic device assemblies incorporating such an interposer and comprising a host device and multiple memory devices are also disclosed, as are methods of fabricating such microelectronic device assemblies.

Provided are a display device and a tiled display device. The display device according to one or more embodiments includes a substrate, transistors above the substrate, a first organic insulating layer above the transistors, a first connection electrode above the first organic insulating layer, and electrically connected to at least one of the transistors, a second connection electrode above the first organic insulating layer, a first power supply line configured to receive a first power voltage, above the first organic insulating layer, and connected to the second connection electrode, and a second organic insulating layer above the first power supply line, and defining an opening area exposing the first power supply line.