A semiconductor structure includes providing a substrate including a first surface and a second surface opposite to the first surface. The first surface is a functional surface. The method also includes forming a plastic seal layer on the first surface of the substrate, and performing a thinning-down process on the second surface of the substrate after forming the plastic seal layer. The plastic seal layer provides support for the substrate during the thinning-down process, and thus warping or cracking of the plastic seal layer 240 may be avoided. In addition, the plastic seal layer can also be used as a material for packaging the substrate. Therefore, after the thinning-down process, the plastic seal layer does not need to be removed. As such, the fabrication process is simplified, and the production cost is reduced.

An electrical device and a method for the manufacture of an electrical device are specified. The device has a carrier with an upper side and a metallized contact surface arranged on it as well as a solder mask layer which covers a part of the upper side but not the contact surface. The solder mask layer has a thickness of 200 nm or less, thereby facilitating subsequent process steps for encapsulating the device.

A process and resultant article of manufacture made by such process comprises forming through vias needed to connect a bottom device layer in a bottom silicon wafer to the one in the top device layer in a top silicon wafer comprising a silicon-on-insulator (SOI) wafer. Through vias are disposed in such a way that they extend from the middle of the line (MOL) interconnect of the top wafer to the buried oxide (BOX) layer of the SOI wafer with appropriate insulation provided to isolate them from the SOI device layer.

During the manufacture of a semiconductor package, a semiconductor wafer including a plurality of bond pads on a surface of the wafer is provided and the surface of the wafer is covered with a dielectric material to form a dielectric layer over the bond pads. Portions of the dielectric layer corresponding to positions of the bond pads are removed to form a plurality of wells, wherein each well is configured to form a through-hole between top and bottom surfaces of the dielectric layer for exposing each bond pad. A conductive material is then deposited into the wells to form a conductive layer between the bond pads and a top surface of the dielectric layer. Thereafter, the semiconductor wafer is singulated to form a plurality of semiconductor packages.

Wafers and methods of forming solder balls include etching a hole in a final redistribution layer over a terminal contact pad on a wafer to expose the terminal contact pad. Solder is injected into the hole using an injection nozzle that is in direct contact with the final redistribution layer. The final redistribution layer is etched back. The injected solder is reflowed to form a solder ball.

A conductive bump assembly may include a passive substrate. The conductive bump assembly may also include a conductive bump pad supported by the passive substrate and surrounded by a first passivation layer opening. The conductive bump assembly may further include a second passivation layer opening on the passive substrate. The second passivation layer opening may be merged with the first passivation layer opening surrounding the conductive bump pad proximate an edge of the passive substrate. The conductive bump assembly may also include a conductive bump on the conductive bump pad.

Wafers include multiple bulk redistribution layers. A contact pad is formed on a surface of one of the bulk redistribution layers. A final redistribution layer is formed on the surface and in contact with the contact pad. Solder is formed on the contact pad. The solder includes a pedestal portion formed to a same height as the final redistribution layer and a ball portion above the pedestal portion.

A vertical semiconductor device is formed in a semiconductor layer having a first surface, a second surface and background doping. A first doped region, doped to a conductivity type opposite that of the background, is formed at the second surface of the semiconductor layer. A second doped region of the same conductivity type as the background is formed at the second surface of the semiconductor layer, inside the first doped region. A portion of the semiconductor layer is removed at the first surface, exposing a new third surface. A third doped region is formed inside the semiconductor layer at the third surface. Electrical contact is made at least to the second doped region (via the second surface) and the third doped region (via the new third surface). In this way, vertical DMOS, IGBT, bipolar transistors, thyristors, and other types of devices can be fabricated in thinned semiconductor, or SOI layers.

A vertical semiconductor device is formed in a semiconductor layer having a first surface, a second surface and background doping. A first doped region, doped to a conductivity type opposite that of the background, is formed at the second surface of the semiconductor layer. A second doped region of the same conductivity type as the background is formed at the second surface of the semiconductor layer, inside the first doped region. A portion of the semiconductor layer is removed at the first surface, exposing a new third surface. A third doped region is formed inside the semiconductor layer at the third surface. Electrical contact is made at least to the second doped region (via the second surface) and the third doped region (via the new third surface). In this way, vertical DMOS, IGBT, bipolar transistors, thyristors, and other types of devices can be fabricated in thinned semiconductor, or SOI layers.

It is disclosed a photoresist cleaning composition for stripping a photoresist pattern having a film thickness of 3-150 ?m, which contains (a) quaternary ammonium hydroxide (b) a mixture of water-soluble organic solvents (c) at least one corrosion inhibitor and (d) water, and a method for treating a substrate therewith.