Implementations of a semiconductor package may include a pin coupled to a substrate. The pin may include a titanium sublayer, a nickel sublayer, and one of a silver and tin intermetallic layer or a copper and tin intermetallic layer, the one of the silver and tin intermetallic layer or the copper and tin intermetallic layer having a melting temperature greater than 260 degrees Celsius. The one of the silver and tin intermetallic layer or the copper and tin intermetallic layer may be formed by reflowing a tin layer and one of a silver layer or copper layer with a silver layer of the substrate where the substrate may be directly coupled to the one of the silver and tin intermetallic layer or the copper and tin intermetallic layer. The substrate may include a copper layer that was directly coupled with the silver layer before the reflow.

A nanowire bonding interconnect for fine-pitch microelectronics is provided. Vertical nanowires created on conductive pads provide a debris-tolerant bonding layer for making direct metal bonds between opposing pads or vias. Nanowires may be grown from a nanoporous medium with a height between 200-1000 nanometers and a height-to-diameter aspect ratio that enables the nanowires to partially collapse against the opposing conductive pads, creating contact pressure for nanowires to direct-bond to opposing pads. Nanowires may have diameters less than 200 nanometers and spacing less than 1 μm from each other to enable contact or direct-bonding between pads and vias with diameters under 5 μm at very fine pitch. The nanowire bonding interconnects may be used with or without tinning, solders, or adhesives. A nanowire forming technique creates a nanoporous layer on conductive pads, creates nanowires within pores of the nanoporous layer, and removes at least part of the nanoporous layer to reveal a layer of nanowires less than 1 μm in height for direct bonding.

Provided is an electronic package, including a first substrate of a first conductive structure and a second substrate of a second conductive structure, where a first conductive layer, a bump body and a metal auxiliary layer of the first conductive structure are sequentially formed on the first substrate, and a metal pillar, a second conductive layer, a metal layer and a solder layer of the second conductive structure are sequentially formed on the second substrate, such that the solder layer is combined with the bump body and the metal auxiliary layer to stack the first substrate and the second substrate.

A package structure and a method for manufacturing a package structure are provided. The package structure includes a first wiring structure and at least one electronic device. The at least one electronic device is connected to the first wiring structure through at least two joint structures. The at least two joint structures respectively include different materials.

A method of forming a semiconductor package. Implementations include forming on a die backside an intermediate metal layer having multiple sublayers, each including a metal selected from the group consisting of titanium, nickel, copper, silver, and combinations thereof. A tin layer is deposited onto the intermediate metal layer and is then reflowed with a silver layer of a substrate to form an intermetallic layer having a melting temperature above 260 degrees Celsius and including an intermetallic consisting of silver and tin and/or an intermetallic consisting of copper and tin. Another method of forming a semiconductor package includes forming a bump on each of a plurality of exposed pads of a top side of a die, each exposed pad surrounded by a passivation layer, each bump including an intermediate metal layer as described above and a tin layer coupled to the intermediate metal layer is reflowed to form an intermetallic layer.

Provided is an electronic package, including a first substrate of a first conductive structure and a second substrate of a second conductive structure, where a first conductive layer, a bump body and a metal auxiliary layer of the first conductive structure are sequentially formed on the first substrate, and a metal pillar, a second conductive layer, a metal layer and a solder layer of the second conductive structure are sequentially formed on the second substrate, such that the solder layer is combined with the bump body and the metal auxiliary layer to stack the first substrate and the second substrate. Therefore, the arrangement of the bump body and the metal auxiliary layer allows complete reaction of the IMCs after reflowing the solder layer, and the volume of the conductive structures will not continue to shrink. As such, the problem of cracking of the conductive structures can be effectively averted.

A semiconductor device according to the embodiment may include a light emitting structure including a first conductivity type semiconductor layer, a second conductivity type semiconductor layer; a first bonding pad disposed on the light emitting structure and electrically connected to the first conductivity type semiconductor layer; a second bonding pad disposed on the light emitting structure and spaced apart from the first bonding pad, and electrically connected to the second conductivity type semiconductor layer; and a reflective layer disposed on the light emitting structure and disposed between the first bonding pad and the second bonding pad. According to the semiconductor device of the embodiment, each of the first bonding pad and the second bonding pad includes a porous metal layer having a plurality of pores and a bonding alloy layer disposed on the porous metal layer.

A package structure and method for forming the same are provided. The package structure includes a first interconnect structure formed over a first substrate, and the first interconnect structure includes a first metal layer. The package structure further includes a second interconnect structure formed over a second substrate. The package structure includes a bonding structure between the first interconnect structure and the second interconnect structure. The bonding structure includes a first intermetallic compound (IMC) and a second intermetallic compound (IMC), a portion of the first IMC protrudes from the sidewall surfaces of the second IMC, and there could be a grain boundary between the first IMC and the second IMC.

A method of forming a semiconductor package. Implementations include forming on a die backside an intermediate metal layer having multiple sublayers, each including a metal selected from the group consisting of titanium, nickel, copper, silver, and combinations thereof. A tin layer is deposited onto the intermediate metal layer and is then reflowed with a silver layer of a substrate to form an intermetallic layer having a melting temperature above 260 degrees Celsius and including an intermetallic consisting of silver and tin and/or an intermetallic consisting of copper and tin. Another method of forming a semiconductor package includes forming a bump on each of a plurality of exposed pads of a top side of a die, each exposed pad surrounded by a passivation layer, each bump including an intermediate metal layer as described above and a tin layer coupled to the intermediate metal layer is reflowed to form an intermetallic layer.

A first conductive pad is connected to a second conductive pad by using a post-transition metal and a nanoporous metal. An example of the post-transition metal is indium. An example of the nanoporous metal is nanoporous gold. A block of the post-transition metal is formed on the first conductive pad. The block of the post-transition metal is coated with a layer of anti-corrosion material. A block of the nanoporous metal is formed on the second conductive pad. The block of the post-transition metal and the block of the nanoporous metal are thermal compressed to form an alloy between the first conductive pad and the second conductive pad.