A semiconductor package includes a base including a first bonding structure; and a first semiconductor chip, including a second bonding structure, the second bonding structure being coupled to the first bonding structure of the base, wherein the first bonding structure includes: a test pad; a first pad being electrically connected to the test pad; and a first insulating layer, wherein the second bonding structure includes: a second pad being electrically connected to the first pad; and a second insulating layer being in contact with the first insulating layer, and wherein at least a portion of the test pad is in contact with the second insulating layer.

A method to fabricate a modular die daisy chain design for wafer level chip scale package (WLCSP) board level reliability testing is described. A wafer is provided having pairs of solder balls electrically connected to each other by underlying metal pads. The wafer is singulated into dies of any of a plurality of sizes as required for testing. Thereafter one of the singulated dies is mounted to a test printed circuit board (PCB). The pairs of solder balls are electrically connected in a daisy chain on the test PCB.

A semiconductor package includes a base including a first bonding structure; and a first semiconductor chip, including a second bonding structure, the second bonding structure being coupled to the first bonding structure of the base, wherein the first bonding structure includes: a test pad; a first pad being electrically connected to the test pad; and a first insulating layer, wherein the second bonding structure includes: a second pad being electrically connected to the first pad; and a second insulating layer being in contact with the first insulating layer, and wherein at least a portion of the test pad is in contact with the second insulating layer.

A bonded structure and a method of forming such a bonded structure are disclosed. The bonded structure can include a first element and a second element. The first element has a first bonding surface including a first nonconductive material and a plurality of first contact pads. The first contact pads are electrically connected to one or more first microelectronic devices in the first element. The second element has a second bonding surface including a second nonconductive material and a plurality of second contact pads. The second contact pads are electrically connected to one or more second microelectronic devices in the second element. The second bonding surface is directly bonded to the first bonding surface without an intervening adhesive to form a bonding interface, and one or more first contact pads is omitted from the first microelectronic element to alter the functionality of the bonded structure.

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.

In a method of manufacturing a semiconductor device according to one embodiment, after a semiconductor wafer including a non-volatile memory, a bonding pad and an insulating film comprised of an organic material is provided, a probe needle is contacted to a surface of the bonding pad located in a second region, and a data is written to the non-volatile memory. Here, the insulating film is formed by performing a first heat treatment to the organic material. Also, after a second heat treatment is performed to the semiconductor wafer, and the non-volatile memory to which the data is written is checked, a barrier layer and a first solder material are formed on the surface of the bonding pad located in a first region by using an electroplating method. Further, a bump electrode is formed in the first region by performing a third heat treatment to the first solder material.

The embodiments of the present invention discloses an arrangement of bond pads on an integrated circuit chip. The integrated circuit chip includes: a first row of bond pads; and a second row of bond pads, wherein bond pads in the first row are positioned alternately with bond pads in the second row, and a short side of the bond pads in the first row and the second row is parallel to a long side of the integrated circuit chip. With this arrangement of bond pads on the integrated circuit chip, the bond pads may occupy a reduced area of a surface of the integrated circuit chip.

Provided is a semiconductor structure including a pad disposed over and electrically connected to an interconnect structure, wherein the pad has a probe mark, and the probe mark has a concave surface; a protective layer conformally covering the pad and the probe mark; and a bonding structure disposed over the protective layer, wherein the bonding structure includes: a bonding dielectric layer includes a first bonding dielectric material and a second bonding dielectric material on the first bonding dielectric material; a first bonding metal layer including a via plug and a metal feature, wherein the via plug penetrates through the first bonding dielectric material and the protective layer to electrically connect to the pad having the probe mark, the metal feature is located on the via plug and the first bonding dielectric material, and the metal feature is laterally surrounded by the second bonding dielectric material.

An integrated circuit structure includes a substrate, a metal pad, a first passivation layer, a second passivation layer, and a conductive bump. The metal pad is over the substrate. The metal pad includes a probing portion and a bumping portion laterally connected to the probing region. The first passivation layer is over the metal pad. The second passivation layer is over the first passivation layer and has an opening. The bumping portion is in the opening. The conductive bump is in the opening of the second passivation layer and contacts the probing portion. The probing portion and the conductive bump are separated by the first passivation layer.

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.