Provided is a semiconductor device having a pad on a semiconductor chip, a first passivation film formed over the semiconductor chip and having an opening portion on the pad of a probe region and a coupling region, a second passivation film formed over the pad and the first passivation film and having an opening portion on the pad of the coupling region, and a rewiring layer formed over the coupling region and the second passivation film and electrically coupled to the pad. The pad of the probe region placed on the periphery side of the semiconductor chip relative to the coupling region has a probe mark and the rewiring layer extends from the coupling region to the center side of the semiconductor chip. The present invention provides a technology capable of achieving size reduction, particularly pitch narrowing, of a semiconductor device.

A semiconductor device structure is provided. The semiconductor device structure includes a semiconductor substrate having a first surface, a second surface opposing the first surface, and sidewalls defining a recess that passes through the semiconductor substrate. A first interconnect layer is within a first dielectric structure disposed along the second surface, and a bonding pad is in the recess and extends to the first interconnect layer. A dielectric filling layer is also within the recess. The dielectric filling layer has an opening over a portion of the bonding pad and a curved upper surface over the bonding pad. A nickel layer is over the bonding pad and in the opening.

A pad is formed on an interlayer insulating film, art insulating film is formed on the interlayer insulating film to cover the pad, and an opening portion exposing a part of the pad is formed in the insulating film. A metal film electrically connected to the pad is formed on the pad exposed from the opening portion and on the insulating film. The metal film integrally includes a first portion on the pad exposed from the opening portion and a second portion on the insulating film. An upper surface of the metal film has a wire bonding region for bonding a wire to the metal film and a probe contact region for bringing the probe into contact with the metal film, the wire bonding region is located on the first portion of the metal film, and the probe contact region is located on the second portion of the metal film.

A method of forming a conductive material on a semiconductor device. The method comprises removing at least a portion of a conductive pad within an aperture in a dielectric material over a substrate. The method further comprises forming a seed material at least within a bottom of the aperture and over the dielectric material, forming a protective material over the seed material within the aperture, and forming a conductive pillar in contact with the seed material through an opening in the protective material over surfaces of the seed material within the aperture. A method of forming an electrical connection between adjacent semiconductor devices, and a semiconductor device, are also described.

To enhance reliability of a test by suppressing defective bonding of a solder in the test of a semiconductor device, a method of manufacturing the semiconductor device includes: preparing a semiconductor wafer that includes a first pad electrode provided with a first cap film and a second pad electrode provided with a second cap film. Further, a polyimide layer that includes a first opening on the first pad electrode and a second opening on the second pad electrode is formed, and then, a rearrangement wiring that is connected to the second pad electrode via the second opening is formed. Next, an opening is formed in the polyimide layer such that an organic reaction layer remains on each of the first pad electrode and a bump land of the rearrangement wiring, then heat processing is performed on the semiconductor wafer, and then, a bump is formed on the rearrangement wiring.

Provided is a semiconductor device including: a first substrate having a first primary surface, a second primary surface, and a side surface; a semiconductor element formed on the first primary surface; a first electrode formed on the first primary surface and connected to the semiconductor element on the first primary surface; a second electrode formed on the second primary surface; a through-electrode formed so as to penetrate the first substrate and connecting the first electrode and the second electrode to each other; a second substrate bonded to the first substrate so as to face the first primary surface; and a third electrode formed on the side surface of the first substrate and connected to the second electrode.

Disclosed are semiconductor devices that include additional gate pads, and methods of fabricating and testing such devices. A device may include a first gate pad, a second gate pad, and a third gate pad. The first gate pad is connected to a gate including a gate oxide layer. The second and third gate pads are part of an electro-static discharge (ESD) protection network for the device. The ESD protection network is initially isolated from the first gate pad and hence from the gate and gate oxide layer. Accordingly, gate oxide integrity (GOI) testing can be effectively performed and the reliability and quality of the gate oxide layer can be checked. The second gate pad can be subsequently connected to the first gate pad to enable the ESD protection network, and the third gate pad can be subsequently connected to an external terminal when the device is packaged.

A semiconductor device including a test pad contact and a method of manufacturing the semiconductor device are disclosed. In an embodiment, a semiconductor device may include a first metal feature and a second metal feature disposed in a single top metal layer over a substrate. A test pad may be formed over and electrically connected to the first metal feature. A first passivation layer may be formed over the second metal feature and the test pad and may cover top and side surfaces of the test pad. A first via may be formed penetrating the first passivation layer and contacting the test pad and a second via may be formed penetrating the first passivation layer and contacting the second metal feature.

Provided is a die stack structure including a first die and a second die. The first die and the second die are bonded together through a hybrid bonding structure. At least one of a first test pad of the first die or a second test pad of the second die has a protrusion of the at least one of the first test pad or the second test pad, and a bonding insulating layer of the hybrid bonding structure covers and contacts with the protrusion, so that the first test pad and the second test pad are electrically isolated from each other.

A device includes a test pad on a chip. A first microbump has a first surface area that is less than a surface area of the test pad. A first conductive path couples the test pad to the first microbump. A second microbump has a second surface area that is less than the surface area of the test pad. A second conductive path couples the test pad to the second microbump.