In various embodiments, a bonded structure is disclosed. The bonded structure can include an element and a passive electronic component having a first surface bonded to the element and a second surface opposite the first surface. The passive electronic component can comprise a first anode terminal bonded to a corresponding second anode terminal of the element and a first cathode terminal bonded to a corresponding second cathode terminal of the element. The first anode terminal and the first cathode terminal can be disposed on the first surface of the passive electronic component.

A semiconductor device includes: a first semiconductor structure including a stacked structure of a first dielectric layer and a first bonding dielectric layer; a second semiconductor structure including a stacked structure of a second dielectric layer and a second bonding dielectric layer; and a bonding pad penetrating the stacked structure of the first dielectric layer and the first bonding dielectric layer, and the stacked structure of the second dielectric layer and the second bonding dielectric layer, wherein the first bonding dielectric layer and the second bonding dielectric layer contact each other, and a first width of a first portion of the bonding pad penetrating the first dielectric layer is greater than each of a second width of a second portion of the bonding pad penetrating the first bonding dielectric layer, and a third width of a third portion of the bonding pad penetrating the second bonding dielectric layer.

A method includes depositing a first dielectric layer on a first substrate of a first device die, etching the first dielectric layer to form a trench, depositing a metallic material in the trench and on a top surface of the first dielectric layer, and performing a chemical mechanical polish (CMP) process to remove a portion of the metallic material from the top surface of the first dielectric layer to form a first metal pad. After the performing of the CMP process, the method selectively etches the first metal pad to form recesses at an edge portion of the first metal pad, deposits a second dielectric layer on a second substrate of a second device die, forms a second metal pad in the second dielectric layer, and bonds the second device die to the first device die.

Provided is a semiconductor module including a main circuit portion, a plurality of circuit electrodes, a plurality of main terminals, and a plurality of wires, in each of semiconductor chips, transistor portions and diode portions have a longitudinal side in a second direction, each of semiconductor chips has a plurality of end sides including a gate-side end side, each of the gate-side end sides is arranged facing a same side in a top view, the plurality of main terminals are arranged on a same side in relation to the main circuit portion so as not to sandwich the main circuit portion in a top view, each of the plurality of wires has a bonding portion, and a longitudinal direction of the bonding portion has an angle in relation to the second direction.

This document discloses techniques, apparatuses, and systems for semiconductor device interconnects formed through volumetric expansion. A semiconductor assembly is described that includes two semiconductor dies. The first semiconductor die and the second semiconductor die are bonded at a dielectric layer of the first semiconductor die and a dielectric layer of the second semiconductor die to create one or more interconnect openings. The first semiconductor die includes a reservoir of conductive material located adjacent to the one or more interconnect openings and having a width greater than a width of the one or more interconnect openings. The reservoir of conductive material is heated to volumetrically expand the reservoir of conductive material through the one or more interconnect openings to form one or more interconnects electrically coupling the first semiconductor die and the second semiconductor die. In this way, a connected semiconductor device may be assembled.

A semiconductor device structure is provided. The semiconductor device structure includes a substrate having a device region and a seal ring region surrounding the device region. The semiconductor device structure includes a seal ring structure over the seal ring region. The seal ring structure surrounds the device region. The semiconductor device structure includes a bonding film over the seal ring structure and the substrate. The semiconductor device structure includes a bonding pad embedded in the bonding film. The bonding pad overlaps the seal ring structure along an axis perpendicular to a first top surface of the substrate, and a second top surface of the bonding pad is substantially level with a third top surface of the bonding film.

A semiconductor device and method of fabrication are described. The device includes a semiconductor RFID IC base layer; a passivation layer located over the base layer and including a metal insert within the passivation layer; a repassivation layer located over the passivation layer and the metal insert; an assembly pad layer located over the repassivation layer. The device includes a first region R1 of the device, where a height of the repassivation layer is given by d.sub.1, and a region R1 is provided with an assembly pad in the assembly pad layer over the repassivation layer that has an area A.sub.1. The device includes an nth region RN of the device, where the height of the repassivation layer is given by d.sub.n, where d.sub.1>d.sub.n, and the region RN is provided with an assembly pad in the bump layer over the repassivation layer, which has an area A.sub.n, where A.sub.n>A.sub.1.