An optical package structure includes a substrate having a first surface, an interposer bonded to the first surface through a bonding layer, the interposer having a first area from a top view perspective, and an optical device on the interposer, having a second area from the top view perspective, the first area being greater than the second area. A method for manufacturing the optical package structure is also provided.

Semiconductor devices and electronics packaging methods include integrated circuit chips having redundant signal bond pads along with signal bond pads connected to the same signal port for non-destructive testing of the integrated circuit chips prior to packaging. Electrical testing is made via the redundant signal bond after which qualified integrated circuit chips can be attached to a pristine and bumped final interposer or printed circuit board to provide increased reliability to the assembled electronic package.

Semiconductor devices and electronics packaging methods include integrated circuit chips having redundant signal bond pads along with signal bond pads connected to the same signal port for non-destructive testing of the integrated circuit chips prior to packaging. Electrical testing is made via the redundant signal bond after which qualified integrated circuit chips can be attached to a pristine and bumped final interposer or printed circuit board to provide increased reliability to the assembled electronic package.

An object of the present invention is to stabilize and strengthen the strength of a bonding part between a metal electrode on a semiconductor chip and metal wiring connected thereto using a simple structure. Provided is a semiconductor device including a metal layer 130 on a surface of a metal electrode 120 formed on a semiconductor chip 110, the metal layer 130 consisting of a metal or an alloy different from a constituent metal of the metal electrode 120, metal wiring 140 is connected to the metal layer 130 via a bonding part 150, wherein the constituent metal of the metal layer 130 is a metal or an alloy different from the constituent metal of the metal electrode 120, and the bonding part 150 has an alloy region harder than the metal wiring 140.

An object of the present invention is to stabilize and strengthen the strength of a bonding part between a metal electrode on a semiconductor chip and metal wiring connected thereto using a simple structure. Provided is a semiconductor device including a metal layer 130 on a surface of a metal electrode 120 formed on a semiconductor chip 110, the metal layer 130 consisting of a metal or an alloy different from a constituent metal of the metal electrode 120, metal wiring 140 is connected to the metal layer 130 via a bonding part 150, wherein the constituent metal of the metal layer 130 is a metal or an alloy different from the constituent metal of the metal electrode 120, and the bonding part 150 has an alloy region harder than the metal wiring 140.

An optical package structure includes a substrate having a first surface, an interposer bonded to the first surface through a bonding layer, the interposer having a first area from a top view perspective, and an optical device on the interposer, having a second area from the top view perspective, the first area being greater than the second area. A method for manufacturing the optical package structure is also provided.

An optical package structure includes a substrate having a first surface, an interposer bonded to the first surface through a bonding layer, the interposer having a first area from a top view perspective, and an optical device on the interposer, having a second area from the top view perspective, the first area being greater than the second area. A method for manufacturing the optical package structure is also provided.

A semiconductor device includes a device wafer having a first side and a second side. The first and second sides are opposite to each other. The semiconductor device includes a plurality of first interconnect structures disposed on the first side of the device wafer. The semiconductor device includes a plurality of second interconnect structures disposed on the second side of the device wafer. The plurality of second interconnect structures comprise a first power rail and a second power rail. The semiconductor device includes a carrier wafer disposed over the plurality of first interconnect structures. The semiconductor device includes an electrostatic discharge (ESD) protection circuit formed over a side of the carrier wafer. The ESD protection circuit is operatively coupled to the first and second power rails.

A semiconductor device includes a device wafer having a first side and a second side. The first and second sides are opposite to each other. The semiconductor device includes a plurality of first interconnect structures disposed on the first side of the device wafer. The semiconductor device includes a plurality of second interconnect structures disposed on the second side of the device wafer. The plurality of second interconnect structures comprise a first power rail and a second power rail. The semiconductor device includes a carrier wafer disposed over the plurality of first interconnect structures. The semiconductor device includes an electrostatic discharge (ESD) protection circuit formed over a side of the carrier wafer. The ESD protection circuit is operatively coupled to the first and second power rails.

Semiconductor devices and electronics packaging methods include integrated circuit chips having redundant signal bond pads along with signal bond pads connected to the same signal port for non-destructive testing of the integrated circuit chips prior to packaging. Electrical testing is made via the redundant signal bond after which qualified integrated circuit chips can be attached to a pristine and bumped final interposer or printed circuit board to provide increased reliability to the assembled electronic package.