A substrate bonding method includes: providing a first and a second substrate; forming, on the first substrate, a first metal micro-bump array including first metal pillar(s) formed on the first substrate and first metal nanowires formed thereon and spaced apart from each other; forming, on the second substrate, a second metal micro-bump array including second metal pillar(s) formed on the second substrate and second metal nanowires formed thereon and spaced apart from each other; pressing the first substrate onto the second substrate, such that the first and second metal micro-bump arrays are positioned and staggered with each other, forming a physically interwoven interlocking structure between the first and second metal nanowires; applying a filling material between the first and second substrates; curing the filling material to form a bonding cavity; and then performing confined heating reflux on the first and second metal micro-bump arrays in the bonding cavity.

A method of making a semiconductor structure includes forming a first contact pad over an interconnect structure. The method further includes forming a second contact pad over the interconnect structure, wherein the second contact pad is electrically separated from the first contact pad. The method further includes depositing a first buffer layer over the interconnect structure, wherein the first buffer layer partially covers the second contact pad, and an edge of the second contact pad extends beyond the first buffer layer.

A SiP-type electronic device, including an electronic chip provided with an electrical interconnection face; a redistribution layer electrically coupled to the electrical interconnection face of the chip; electrical connection elements electrically coupled to the chip by the redistribution layer which is arranged between the chip and the connection elements; a first metal layer arranged on the side of a second face of the chip and secured to this second face; an encapsulation material arranged around the chip, between the redistribution layer and the first metal layer; a second metal layer including a first face secured by direct bonding to the first metal layer; a substrate arranged against a second face of the second metal layer.

There is provided a bonding wire for a semiconductor device including a coating layer having Pd as a main component on a surface of a Cu alloy core material and a skin alloy layer containing Au and Pd on a surface of the coating layer, the bonding wire further improving 2nd bondability on a Pd-plated lead frame and achieving excellent ball bondability even in a high-humidity heating condition. The bonding wire for a semiconductor device including the coating layer having Pd as a main component on the surface of the Cu alloy core material and the skin alloy layer containing Au and Pd on the surface of the coating layer has a Cu concentration of 1 to 10 at % at an outermost surface thereof and has the core material containing either or both of Pd and Pt in a total amount of 0.1 to 3.0% by mass, thereby achieving improvement in the 2nd bondability and excellent ball bondability in the high-humidity heating condition. Furthermore, a maximum concentration of Au in the skin alloy layer is preferably 15 at % to 75 at %.

There is provided a bonding wire for a semiconductor device including a coating layer having Pd as a main component on a surface of a Cu alloy core material and a skin alloy layer containing Au and Pd on a surface of the coating layer, the bonding wire further improving 2nd bondability on a Pd-plated lead frame and achieving excellent ball bondability even in a high-humidity heating condition. The bonding wire for a semiconductor device including the coating layer having Pd as a main component on the surface of the Cu alloy core material and the skin alloy layer containing Au and Pd on the surface of the coating layer has a Cu concentration of 1 to 10 at % at an outermost surface thereof and has the core material containing either or both of Pd and Pt in a total amount of 0.1 to 3.0% by mass, thereby achieving improvement in the 2nd bondability and excellent ball bondability in the high-humidity heating condition. Furthermore, a maximum concentration of Au in the skin alloy layer is preferably 15 at % to 75 at %.

Discloses is a method of bonding a semiconductor device, for example, a sintering bonding method for a semiconductor device that can mix pure particles and copper (I) oxide nano particles on a metal substrate. The paste of the present invention may provide low-cost copper paste increasing a copper density as a bonding material when bonding a semiconductor chip continuously used at a high temperature. The copper paste of the present invention may suppress the occurrence of pores or cracks when sintering by heating the copper paste under the reduction atmosphere as saving material costs and implementing an optimum high heat-resistance bonding.

The present invention provides a bonding wire which can satisfy bonding reliability, spring performance, and chip damage performance required in high-density packaging. A bonding wire contains one or more of In, Ga, and Cd for a total of 0.05 to 5 at %, and a balance being made up of Ag and incidental impurities.

The present invention provides a bonding wire which can satisfy bonding reliability, spring performance, and chip damage performance required in high-density packaging. A bonding wire contains one or more of In, Ga, and Cd for a total of 0.05 to 5 at %, and a balance being made up of Ag and incidental impurities.

In various embodiments, a die is provided. The die may include a die body, and at least one of a front side metallization structure on a front side of the die body and a back side metallization structure on a back side of the die body such that the die is plane or includes a positive radius of curvature at a die attach process temperature range.

A hybrid bonded structure including a first integrated circuit component and a second integrated circuit component is provided. The first integrated circuit component includes a first dielectric layer, first conductors and isolation structures. The first conductors and the isolation structures are embedded in the first dielectric layer. The isolation structures are electrically insulated from the first conductors and surround the first conductors. The second integrated circuit component includes a second dielectric layer and second conductors. The second conductors are embedded in the second dielectric layer. The first dielectric layer is bonded to the second dielectric layer and the first conductors are bonded to the second conductors.