Semiconductor devices having one or more vias filled with an electrically conductive material are disclosed herein. In one embodiment, a semiconductor device includes a semiconductor substrate having a first side, a plurality of circuit elements proximate to the first side, and a second side opposite the first side. A via can extend between the first and second sides, and a conductive material in the via can extend beyond the second side of the substrate to define a projecting portion of the conductive material. The semiconductor device can have a tall conductive pillar formed over the second side and surrounding the projecting portion of the conductive material, and a short conductive pad formed over the first side and electrically coupled to the conductive material in the via.

The present application provides a method for fabricating a semiconductor device including providing a semiconductor substrate, forming a first stress-relieving structure including a first conductive frame above the semiconductor substrate and a plurality of first insulating pillars within the first conductive frame, forming a second stress-relieving structure comprising a plurality of second conductive pillars above the first stress-relieving structure and a second insulating frame, the plurality of second conductive pillars are disposed within the second conductive frame, wherein the plurality of second conductive pillars is disposed correspondingly above the plurality of first insulating pillars, and the second insulating frame is disposed correspondingly above the first conductive frame; and forming a conductive structure including a supporting portion above the second stress-relieving structure, a conductive portion adjacent to the supporting portion, and a plurality of spacers attached to two sides of the conductive portion.

The present application provides a method for fabricating a semiconductor device including providing a semiconductor substrate, forming a first stress-relieving structure including a first conductive frame above the semiconductor substrate and a plurality of first insulating pillars within the first conductive frame, forming a second stress-relieving structure comprising a plurality of second conductive pillars above the first stress-relieving structure and a second insulating frame, the plurality of second conductive pillars are disposed within the second conductive frame, wherein the plurality of second conductive pillars is disposed correspondingly above the plurality of first insulating pillars, and the second insulating frame is disposed correspondingly above the first conductive frame; and forming a conductive structure including a supporting portion above the second stress-relieving structure, a conductive portion adjacent to the supporting portion, and a plurality of spacers attached to two sides of the conductive portion.

The present disclosure provides a method for preparing a semiconductor device with a composite dielectric structure. The method includes forming a photoresist pattern structure over a first semiconductor die. The method also includes forming a second dielectric layer surrounding the photoresist pattern structure, and removing the photoresist pattern structure to form a first opening in the second dielectric layer. The method further includes forming dielectric spacers along sidewalls of the first opening, and forming an interconnect structure surrounded by the dielectric spacers. In addition, the method includes bonding a second semiconductor die to the second dielectric layer. The second semiconductor die includes a second conductive pad facing the interconnect structure, and the second conductive pad is electrically connected to the first conductive pad of the first semiconductor die through the interconnect structure.

The present disclosure provides a method for preparing a semiconductor device with a composite dielectric structure. The method includes forming a photoresist pattern structure over a first semiconductor die. The method also includes forming a second dielectric layer surrounding the photoresist pattern structure, and removing the photoresist pattern structure to form a first opening in the second dielectric layer. The method further includes forming dielectric spacers along sidewalls of the first opening, and forming an interconnect structure surrounded by the dielectric spacers. In addition, the method includes bonding a second semiconductor die to the second dielectric layer. The second semiconductor die includes a second conductive pad facing the interconnect structure, and the second conductive pad is electrically connected to the first conductive pad of the first semiconductor die through the interconnect structure.

A device and method of manufacture is provided that utilize a dummy pad feature adjacent contact pads. The contact pads may be contact pads in an integrated fan-out package in which a molding compound is placed along sidewalls of a die and the contact pads extend over the die and the molding compound. The contact pads are electrically coupled to the die using one or more redistribution layers. The dummy pad features are electrically isolated from the contact pads. In some embodiments, the dummy pad features partially encircle the contact pads and are located in a corner region of the molding compound, a corner region of the die, and/or an interface region between an edge of the die and the molding compound.

First conductive layer is connected to an impurity region which is a source region or an emitter region. A first conductive layer having an emitter pad and a second conductive layer having a Kelvin emitter pad and a relay pad are separated. A plane occupied area of the Kelvin emitter pad is smaller than a plane occupied area of the emitter 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 via for semiconductor devices is disclosed. Implementations of vias for semiconductor devices may include: a semiconductor substrate that includes a first side; a via extending from the first side of the semiconductor substrate to a pad; a polymer layer coupled along an entire sidewall of the via, the polymer layer in direct contact with the pad; and a metal layer directly coupled over the polymer layer and directly coupled with the pad.

A via for semiconductor devices is disclosed. Implementations of vias for semiconductor devices may include: a semiconductor substrate that includes a first side; a via extending from the first side of the semiconductor substrate to a pad; a polymer layer coupled along an entire sidewall of the via, the polymer layer in direct contact with the pad; and a metal layer directly coupled over the polymer layer and directly coupled with the pad.