A three-dimensional (3D) bonded semiconductor structure is provided in which a first bonding oxide layer of a first semiconductor structure is bonded to a second bonding oxide layer of a second semiconductor structure. Each of the first and second bonding oxide layers has a metallic bonding structure embedded therein, wherein each metallic bonding structure contains a columnar grain microstructure. Furthermore, at least one columnar grain extends across a bonding interface that is present between the metallic bonding structures. The presence of the columnar grain microstructure in the metallic bonding structures, together with at least one columnar grain microstructure extending across the bonding interface between the two bonded metallic bonding structures, can provide a 3D bonded structure having mechanical bonding strength and electrical performance enhancements.

A Cu.sub.3Sn electrical interconnect and method of making same in an electrical device, such as for hybrid bond 3D-integration of the electrical device with one or more other electrical devices. The method of forming the Cu.sub.3Sn electrical interconnect includes: depositing a Sn layer in the via hole; depositing a Cu layer atop and in contact with the Sn layer; and heating the Sn layer and the Cu layer such that the Sn and Cu layers diffuse together to form a Cu.sub.3Sn interconnect in the via hole. During the heating, a diffusion front between the Sn and Cu layers moves in a direction toward the Cu layer as initially deposited, such that any remaining Cu layer or any voids formed during the diffusion are at an upper region of the formed Cu.sub.3Sn interconnect in the via hole, thereby allowing such voids or remaining material to be easily removed.

A Cu.sub.3Sn electrical interconnect and method of making same in an electrical device, such as for hybrid bond 3D-integration of the electrical device with one or more other electrical devices. The method of forming the Cu.sub.3Sn electrical interconnect includes: depositing a Sn layer in the via hole; depositing a Cu layer atop and in contact with the Sn layer; and heating the Sn layer and the Cu layer such that the Sn and Cu layers diffuse together to form a Cu.sub.3Sn interconnect in the via hole. During the heating, a diffusion front between the Sn and Cu layers moves in a direction toward the Cu layer as initially deposited, such that any remaining Cu layer or any voids formed during the diffusion are at an upper region of the formed Cu.sub.3Sn interconnect in the via hole, thereby allowing such voids or remaining material to be easily removed.

The present disclosure provides a semiconductor device. The semiconductor device includes a first electrode and a second electrode disposed on a substrate, a first conductive bump disposed on the first electrode, and a second conductive bump disposed on the second electrode, wherein, the first conductive bump has a first convex top surface, the second conductive bump has a second convex top surface, and the top of the first convex top surface and the top of the second convex top surface substantially have a same horizontal height. The composition of the first electrode includes a first metal. The composition of the first conductive bump includes the first metal and a second metal. The content of the first metal in the first conductive bump is gradually decreased in a direction away from the first electrode.

A semiconductor die and a method for manufacturing a semiconductor die are disclosed. In an embodiment a semiconductor die includes a base body having a semiconductor material and a surface with two contact areas having contact pads at which the semiconductor die is electrically contactable and two metal caps arranged directly at the contact pads.

A semiconductor chip includes a semiconductor substrate made of SiC, a front surface electrode formed in a principal surface of the semiconductor substrate, and a rear surface electrode (drain electrode) formed in a rear surface of the semiconductor substrate. The front surface electrode is bonded to a wire, and includes an Al alloy film containing a high melting-point metal. The Al alloy film contains a columnar Al crystal which extends along a thickness direction of the Al alloy film, and an intermetallic compound is precipitated therein.

A first semiconductor structure including a first bonding oxide layer having a first metallic bonding structure embedded therein and a second semiconductor structure including a second bonding oxide layer having a second metallic bonding structure embedded therein are provided. A nitride surface treatment process is performed to provide a nitrided surface layer to each structure. Each nitrided surface layer includes nitridized oxide regions located in an upper portion of the bonding oxide layer and nitridized metallic regions located in an upper portion of the metallic bonding structures. The nitrogen within the nitridized metallic regions is then removed to restore the upper portion of the metallic bonding structures to its original composition. Bonding is performed to form a dielectric bonding interface between the nitridized oxide regions present in the first and second structures, and a metallic bonding interface between the first and second metallic bonding structures.

A first semiconductor structure including a first bonding oxide layer having a first metallic bonding structure embedded therein and a second semiconductor structure including a second bonding oxide layer having a second metallic bonding structure embedded therein are provided. A nitride surface treatment process is performed to provide a nitrided surface layer to each structure. Each nitrided surface layer includes nitridized oxide regions located in an upper portion of the bonding oxide layer and nitridized metallic regions located in an upper portion of the metallic bonding structures. The nitrogen within the nitridized metallic regions is then removed to restore the upper portion of the metallic bonding structures to its original composition. Bonding is performed to form a dielectric bonding interface between the nitridized oxide regions present in the first and second structures, and a metallic bonding interface between the first and second metallic bonding structures.

A semiconductor structure includes a first contact pad over a passivation layer, wherein the first contact pad is in a circuit region. The semiconductor structure further includes a plurality of second contact pads over the passivation layer, wherein each second contact pad of the plurality of second contact pads is in a non-circuit region. The semiconductor structure further includes a first buffer layer over the first contact pad and over a first second contact pad of the plurality of second contact pads. The semiconductor structure further includes a second buffer layer over the first buffer layer, the first contact pad, the first second contact pad and a portion of a second second contact pad of the plurality of second contact pads, wherein the second buffer layer exposes a portion of the second second contact pad of the plurality of second contact pads.

A semiconductor device according to an embodiment comprises a substrate, an epitaxial layer on the substrate, and a cluster including a plurality of particles disposed on the epitaxial layer, the particles being disposed to be apart from each other, and contacting the epitaxial layer.