According to an embodiment, a semiconductor device includes a first chip including a substrate, and a second chip bonded to the first chip at a first surface. Each of the first chip and the second chip includes an element region, and an end region including a chip end portion. The first chip includes a plurality of first electrodes that are arranged on the first surface in the end region and are in an electrically uncoupled state. The second chip includes a plurality of second electrodes that are arranged on the first surface in the end region, are in an electrically uncoupled state, and are respectively in contact with the first electrodes.

The present technology relates to a semiconductor device in which a MIM capacitive element can be formed without any process damage, and a method for manufacturing the semiconductor device. In a semiconductor device, wiring layers of a first multilayer wiring layer formed on a first semiconductor substrate and a second multilayer wiring layer formed on a second semiconductor substrate are bonded to each other by wafer bonding. The semiconductor device includes a capacitive element including an upper electrode, a lower electrode, and a capacitive insulating film between the upper electrode and the lower electrode. One electrode of the upper electrode and the lower electrode is formed with a first conductive layer of the first multilayer wiring layer and a second conductive layer of the second multilayer wiring layer. The present technology can be applied to a semiconductor device or the like formed by joining two semiconductor substrates, for example.

A semiconductor package includes a chip, a redistribution structure, and first under-ball metallurgies patterns. The chip includes conductive posts exposed at an active surface. The redistribution structure is disposed on the active surface. The redistribution structure includes a first dielectric layer, a topmost metallization layer, and a second dielectric layer. The first dielectric layer includes first openings exposing the conductive posts of the chip. The topmost metallization layer is disposed over the first dielectric layer and is electrically connected to the conductive posts. The topmost metallization layer comprises first contact pads and routing traces connected to the first contact pads. The second dielectric layer is disposed on the topmost metallization layer and includes second openings exposing the first contact pads. The first under-ball metallurgies patterns are disposed on the first contact pads, extending on and contacting sidewalls and top surfaces of the first contact pads.

A semiconductor device including a first die and a second die bonded to one another. The first die includes a first passivation layer over a substrate, and first bond pads in the first passivation layer. The second die includes a second passivation layer, which may be bonded to the first passivation layer, and second bond pads in the second passivation layer, which may be bonded to the first bond pads. The second bond pads include inner bond pads and outer bond pads. The outer bond pads may have a greater diameter than the inner bond pads as well as the first bond pads.

A semiconductor package and a manufacturing method for the semiconductor package are provided. The semiconductor package at least has chip and a redistribution layer. The redistribution layer is disposed on the chip. The redistribution layer includes joining portions having first pads and second pads surrounding the chip. The first pads are arranged around a location of the chip and the second pads are arranged over the location of the chip. The second pads located closer to the chip are narrower than the first pads located further away from the chip.

A semiconductor device including a first die and a second die bonded to one another. The first die includes a first passivation layer over a substrate, and first bond pads in the first passivation layer. The second die includes a second passivation layer, which may be bonded to the first passivation layer, and second bond pads in the second passivation layer, which may be bonded to the first bond pads. The second bond pads include inner bond pads and outer bond pads. The outer bond pads may have a greater diameter than the inner bond pads as well as the first bond pads.

A semiconductor device includes a first semiconductor chip having a first bonding layer and a second semiconductor chip stacked on the first semiconductor chip and having a second bonding layer. The first bonding layer includes a first bonding pad, a plurality of first internal vias, and a first interconnection connecting the first bonding pad and the plurality of first internal vias. The second bonding layer includes a second bonding pad bonded to the first bonding pad. An upper surface of the first interconnection and an upper surface of the first bonding pad are coplanar with an upper surface of the first bonding layer. The first interconnection is electrically connected to the plurality of different first internal lines through the plurality of first internal vias.

Methods of forming bonded semiconductor structures include providing a first semiconductor structure including a device structure, bonding a second semiconductor structure to the first semiconductor structure below about 400 C., forming a through wafer interconnect through the second semiconductor structure and into the first semiconductor structure, and bonding a third semiconductor structure to the second semiconductor structure on a side thereof opposite the first semiconductor structure. In additional embodiments, a first semiconductor structure is provided. Ions are implanted into a second semiconductor structure. The second semiconductor structure is bonded to the first semiconductor structure. The second semiconductor structure is fractured along an ion implant plane, a through wafer interconnect is formed at least partially through the first and second semiconductor structures, and a third semiconductor structure is bonded to the second semiconductor structure on a side thereof opposite the first semiconductor structure. Bonded semiconductor structures are formed using such methods.

Wirebond bondpads on semiconductor packages that result in reduced cross-talk and/or interference between vertical wires are disclosed. The vertical wirebonds may be disposed in the semiconductor package with stacked dies, where the wires are substantially normal to the bondpads to which the vertical wirebonds are attached on the dies. The wirebond bondpads may include signal pads that carry input/output (I/O) to/from the die package, as well as ground bondpads. The bondpads may have widths that are greater than the space between adjacent bondpads. Bondpads may be fabricated to be larger than the size requirements for reliable wirebond formation on the bondpads. For a fixed pitch bondpad configuration, the size of the signal bondpads adjacent to the ground bondpads may be greater than half of the pitch. By increasing the size of the signal bondpads adjacent to a ground line relative to the space therebetween, improved cross-talk performance may be achieved.

Methods of forming bonded semiconductor structures include providing a first semiconductor structure including a device structure, bonding a second semiconductor structure to the first semiconductor structure below about 400 C., forming a through wafer interconnect through the second semiconductor structure and into the first semiconductor structure, and bonding a third semiconductor structure to the second semiconductor structure on a side thereof opposite the first semiconductor structure. In additional embodiments, a first semiconductor structure is provided. Ions are implanted into a second semiconductor structure. The second semiconductor structure is bonded to the first semiconductor structure. The second semiconductor structure is fractured along an ion implant plane, a through wafer interconnect is formed at least partially through the first and second semiconductor structures, and a third semiconductor structure is bonded to the second semiconductor structure on a side thereof opposite the first semiconductor structure. Bonded semiconductor structures are formed using such methods.