A first semiconductor die includes first semiconductor devices located over a first substrate, first interconnect-level dielectric material layers embedding first metal interconnect structures and located on the first semiconductor devices, and a first pad-level dielectric layer located on the first interconnect-level dielectric material layers and embedding first bonding pads. Each of the first bonding pads includes a first proximal horizontal surface and at least one first distal horizontal surface that is more distal from the first substrate than the first proximal horizontal surface is from the first substrate and has a lesser total area than a total area of the first proximal horizontal surface. A second semiconductor die including second bonding pads that are embedded in a second pad-level dielectric layer can be bonded to a respective distal surface of the first bonding pads.

A silicon carbide device includes a silicon carbide substrate, a contact layer including nickel, silicon and aluminum, a barrier layer structure including titanium and tungsten, and a metallization layer including copper. The contact layer is located on the silicon carbide substrate. The contact layer is located between the silicon carbide substrate and at least a part of the barrier layer structure. The barrier layer structure is located between the silicon carbide substrate and the metallization layer.

A silicon carbide device includes a silicon carbide substrate, a contact layer including nickel, silicon and aluminum, a barrier layer structure including titanium and tungsten, and a metallization layer including copper. The contact layer is located on the silicon carbide substrate. The contact layer is located between the silicon carbide substrate and at least a part of the barrier layer structure. The barrier layer structure is located between the silicon carbide substrate and the metallization layer.

A semiconductor structure includes a substrate, a passivation layer on the substrate, a post-passivation interconnect (PPI) structure on the passivation layer, and a polymer layer covering the PPI structure and the passivation layer. The PPI structure includes a step structure disposed on the passivation layer and around a lower edge of the PPI structure.

A semiconductor structure includes a substrate, a passivation layer on the substrate, a post-passivation interconnect (PPI) structure on the passivation layer, and a polymer layer covering the PPI structure and the passivation layer. The PPI structure includes a step structure disposed on the passivation layer and around a lower edge of the PPI structure.

Technologies for plasma oxidation protection during hybrid bonding of semiconductor devices includes forming a blocking layer on a metallic bonding pad formed in a bonding surface of a semiconductor device to be bonded and performing a surface treatment on the bonding surface to increase the bonding strength of the bonding surface and contemporaneously remove the blocking layer from the metallic bonding pad. In an illustrative embodiment, the blocking layer is embodied as a self-assembled monolayer (SAM), and the surface treatment is embodied as a surface activation plasma (SAP) treatment. A diffusion barrier layer, such as a silicon carbon nitride layer, may form the bonding surface in some embodiments to reduce diffusion of the metallic bonding pad during an annealing treatment of the bonding process.

A device is disclosed. The device includes a gate conductor, a first source-drain region and a second source-drain region. The device includes a first air gap space between the first source-drain region and a first side of the gate conductor and a second air gap space between the second source-drain region and a second side of the gate conductor. A hard mask layer that includes holes is under the gate conductor, the first source-drain region, the second source-drain region and the air gap spaces. A planar dielectric layer is under the hard mask.

A device is disclosed. The device includes a gate conductor, a first source-drain region and a second source-drain region. The device includes a first air gap space between the first source-drain region and a first side of the gate conductor and a second air gap space between the second source-drain region and a second side of the gate conductor. A hard mask layer that includes holes is under the gate conductor, the first source-drain region, the second source-drain region and the air gap spaces. A planar dielectric layer is under the hard mask.

The present application discloses a semiconductor device and a method for fabricating the semiconductor device. The semiconductor device includes a first semiconductor structure and a first connecting structure, wherein the first connecting structure includes a first connecting insulating layer positioned on the first semiconductor structure, two first conductive layers positioned in the first connecting insulating layer, and a first porous layer positioned between the two first conductive layers. A porosity of the first porous layer is between about 25% and about 100%. The first semiconductor structure includes a plurality of first composite conductive features, wherein at least one of the plurality of first composite conductive features includes a first protection liner, a first graphene liner in the first protection liner and a first core conductor in the first graphene liner.

The present disclosure provides a die assembly. The die assembly includes a first die, a second die and a third die stacked together. The first die includes a plurality of first metal lines facing a plurality of second metal lines of the second die, and a second substrate beneath the second metal lines faces a plurality of third metal lines of the third die. The die assembly further includes at least one first plug, a first redistribution layer and a second redistribution layer. The first plug penetrates through the second substrate to connect to at least one of the second metal lines. A first redistribution layer physically connects at least one of the first metal lines to at least one of the second metal lines, and a second redistribution layer physically connects at least one of the third metal lines to the first plug.