Various embodiments of the present disclosure are directed towards an integrated circuit (IC) chip comprising a semiconductor device that is inverted and that overlies a dielectric region inset into a top of a semiconductor substrate. An interconnect structure overlies the semiconductor substrate and the dielectric region and further comprises an intermetal dielectric (IMD) layer. The IMD layer is bonded to the top of the semiconductor substrate and accommodates a pad. A semiconductor layer overlies the interconnect structure, and the semiconductor device is in the semiconductor layer, between the semiconductor layer and the interconnect structure. The semiconductor device comprises a first source/drain electrode overlying the dielectric region and further overlying and electrically coupled to the pad. The dielectric region reduces substrate capacitance to decrease substrate power loss and may, for example, be a cavity or a dielectric layer. A contact extends through the semiconductor layer to the pad.

Various embodiments of the present disclosure are directed towards an integrated circuit (IC) chip comprising a semiconductor device that is inverted and that overlies a dielectric region inset into a top of a semiconductor substrate. An interconnect structure overlies the semiconductor substrate and the dielectric region and further comprises an intermetal dielectric (IMD) layer. The IMD layer is bonded to the top of the semiconductor substrate and accommodates a pad. A semiconductor layer overlies the interconnect structure, and the semiconductor device is in the semiconductor layer, between the semiconductor layer and the interconnect structure. The semiconductor device comprises a first source/drain electrode overlying the dielectric region and further overlying and electrically coupled to the pad. The dielectric region reduces substrate capacitance to decrease substrate power loss and may, for example, be a cavity or a dielectric layer. A contact extends through the semiconductor layer to the pad.

Reduced-profile semiconductor device apparatus are achieved by thinning a semiconductive device substrate at a backside surface to expose a through-silicon via pillar, forming a recess to further expose the through-silicon via pillar, and by seating an electrical bump in the recess to contact both the through-silicon via pillar and the recess. In an embodiment, the electrical bump contacts a semiconductor package substrate to form a low-profile semiconductor device apparatus. In an embodiment, the electrical bump contacts a subsequent die to form a low-profile semiconductor device apparatus.

Reduced-profile semiconductor device apparatus are achieved by thinning a semiconductive device substrate at a backside surface to expose a through-silicon via pillar, forming a recess to further expose the through-silicon via pillar, and by seating an electrical bump in the recess to contact both the through-silicon via pillar and the recess. In an embodiment, the electrical bump contacts a semiconductor package substrate to form a low-profile semiconductor device apparatus. In an embodiment, the electrical bump contacts a subsequent die to form a low-profile semiconductor device apparatus.

An optoelectronic element includes an optoelectronic unit, a first metal layer, a second metal layer, a conductive layer and a transparent structure. The optoelectronic unit has a central line in a top view, a top surface, and a bottom surface. The second metal layer is formed on the top surface, and has an extension portion crossing over the central line and extending to the first metal layer. The conductive layer covers the first metal layer and the extension portion. The transparent structure covers the bottom surface without covering the top surface.

A method for a through-silicon-via (TSV) connector includes: providing a semiconductor wafer with a silicon substrate, wherein the semiconductor wafer has a frontside and a backside opposite to the frontside thereof; forming multiple holes in the silicon substrate of the semiconductor wafer; forming a first insulating layer at a sidewall and bottom of each of the holes; forming a metal layer over the semiconductor wafer and in each of the holes; polishing the metal layer outside each of the holes to expose a frontside surface of the metal layer in each of the holes; forming multiple metal bumps or pads each on the frontside surface of the metal layer in at least one of the holes; grinding a backside of the silicon substrate of the semiconductor wafer to expose a backside surface of the metal layer in each of the holes, wherein the backside surface of the metal layer in each of the holes and a backside surface of the silicon substrate of the semiconductor wafer are coplanar; and cutting the semiconductor wafer to form multiple through-silicon-via (TSV) connectors.

A method for a through-silicon-via (TSV) connector includes: providing a semiconductor wafer with a silicon substrate, wherein the semiconductor wafer has a frontside and a backside opposite to the frontside thereof; forming multiple holes in the silicon substrate of the semiconductor wafer; forming a first insulating layer at a sidewall and bottom of each of the holes; forming a metal layer over the semiconductor wafer and in each of the holes; polishing the metal layer outside each of the holes to expose a frontside surface of the metal layer in each of the holes; forming multiple metal bumps or pads each on the frontside surface of the metal layer in at least one of the holes; grinding a backside of the silicon substrate of the semiconductor wafer to expose a backside surface of the metal layer in each of the holes, wherein the backside surface of the metal layer in each of the holes and a backside surface of the silicon substrate of the semiconductor wafer are coplanar; and cutting the semiconductor wafer to form multiple through-silicon-via (TSV) connectors.

A semiconductor device and a method of forming the same are provided. The semiconductor device includes a first logic die including a first through via, an image sensor die hybrid bonded to the first logic die, and a second logic die bonded to the first logic die. A front side of the first logic die facing a front side of the image sensor die. A front side of the second logic die facing a backside of the first logic die. The second logic die comprising a first conductive pad electrically coupled to the first through via.

A semiconductor device and a method of forming the same are provided. The semiconductor device includes a first logic die including a first through via, an image sensor die hybrid bonded to the first logic die, and a second logic die bonded to the first logic die. A front side of the first logic die facing a front side of the image sensor die. A front side of the second logic die facing a backside of the first logic die. The second logic die comprising a first conductive pad electrically coupled to the first through via.

There is set forth herein an optoelectrical device, comprising: a substrate; an interposer dielectric stack formed on the substrate, the interposer dielectric stack including a base interposer dielectric stack, a photonics device dielectric stack, and a bond layer that integrally bonds the photonics device dielectric stack to the base interposer dielectric stack. There is set forth herein a method comprising building an interposer base structure on a first wafer having a first substrate, including fabricating a plurality of through vias in the first substrate and fabricating within an interposer base dielectric stack formed on the first substrate one or more metallization layers; and building a photonics structure on a second wafer having a second substrate, including fabricating one or more photonics devices within a photonics device dielectric stack formed on the second substrate.