A first semiconductor structure including a first bonding oxide layer having a first metallic structure embedded therein and a second semiconductor structure including a second bonding oxide layer having second metallic structure embedded therein are provided. A high-k dielectric material is formed on a surface of the first metallic structure. A nitride surface treatment process is performed to provide a nitrided surface layer to each structure. The nitrided surface layer includes nitridized oxide regions located in an upper portion of the bonding oxide layers and either a nitridized high-k dielectric material located in at least an upper portion of the high k dielectric material or a nitridized metallic region located in an upper portion of the second metallic structure. The nitrogen within the nitridized metallic region is then selectively removed to restore the upper portion of the second metallic structure to its original composition. Bonding is then performed.

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 an embodiment, an interposer has a first side, a first integrated circuit device attached to the first side of the interposer with a first set of conductive connectors, each of the first set of conductive connectors having a first height, a first die package attached to the first side of the interposer with a second set of conductive connectors, the second set of conductive connectors including a first conductive connector and a second conductive connector, the first conductive connector having a second height, the second conductive connector having a third height, the third height being different than the second height, a first dummy conductive connector being between the first side of the interposer and the first die package, an underfill disposed beneath the first integrated circuit device and the first die package, and an encapsulant disposed around the first integrated circuit device and the first die package.

Hybrid bonding systems and methods for semiconductor wafers are disclosed. In one embodiment, a hybrid bonding system for semiconductor wafers includes a chamber and a plurality of sub-chambers disposed within the chamber. A robotics handler is disposed within the chamber that is adapted to move a plurality of semiconductor wafers within the chamber between the plurality of sub-chambers. The plurality of sub-chambers includes a first sub-chamber adapted to remove a protection layer from the plurality of semiconductor wafers, and a second sub-chamber adapted to activate top surfaces of the plurality of semiconductor wafers prior to hybrid bonding the plurality of semiconductor wafers together. The plurality of sub-chambers also includes a third sub-chamber adapted to align the plurality of semiconductor wafers and hybrid bond the plurality of semiconductor wafers together.

A semiconductor package includes a first semiconductor chip and a second semiconductor chip. The first semiconductor chip includes a peripheral region having a groove and a bonding region that is disposed higher than the groove. The second semiconductor chip is disposed in the bonding region of the first semiconductor chip. The second semiconductor chip is directly electrically connected to the first semiconductor chip. The second semiconductor chip includes an overhang protruded from the bonding region. The overhang is spaced apart from a bottom surface of the groove. Thus, a bonding failure, which may be caused by particles generated during a cutting the wafer and adhered to the edge portion of the second semiconductor chip, between the first semiconductor chip and the second semiconductor chip might be avoided.

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.

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.

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.

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.

A wafer bonding method includes placing a first wafer on a first bonding framework including a plurality of outlet holes around a periphery of the first bonding framework. A second wafer is placed on a second bonding framework that includes a plurality of inlet holes around a periphery of the second bonding framework. The first bonding framework is in overlapping relation to the second bonding framework such that a gap exist between the first wafer and the second wafer. A gas stream is circulated through the gap between the first wafer and the second wafer entering the gap through one or more of the plurality of inlet holes and exiting the gap through one or more of the plurality of outlet holes. The gas stream replaces any existing ambient moisture from the gap between the first wafer and the second wafer.