Proximity coupling interconnect packaging systems and methods. A semiconductor package assembly comprises a substrate, a first semiconductor die disposed adjacent the substrate, and a second semiconductor die stacked over the first semiconductor die. There is at least one proximity coupling interconnect between the first semiconductor die and the second semiconductor die, the proximity coupling interconnect comprising a first conductive pad on the first coupling face on the first semiconductor die and a second conductive pad on a second coupling face of the second semiconductor die, the second conductive pad spaced apart from the first conductive pad by a gap distance and aligned with the first conductive pad. An electrical connector is positioned laterally apart from the proximity coupling interconnect and extends between the second semiconductor die and the substrate, the position of the electrical connector defining the alignment of the first conductive pad and the second conductive pad.

A semiconductor package includes a first semiconductor chip positioned above a first substrate. A second substrate is positioned above the first substrate. The first semiconductor chip is positioned between the first substrate and the second substrate. A plurality of support structures are disposed between the second substrate and the first semiconductor chip. Connection members are disposed between the first substrate and the second substrate. The connection members electrically connect the first substrate to the second substrate. A molding layer fills a space between the first substrate and the second substrate. The molding layer is disposed on the first semiconductor chip and the connection members.

A solder connection may be surrounded by a solder locking layer (1210, 2210) and may be recessed in a hole (1230) in that layer. The recess may be obtained by evaporating a vaporizable portion (1250) of the solder connection. Other features are also provided.

A semiconductor device includes a dielectric interposer, a first redistribution layer, a second redistribution layer and conductive structures. The conductive structures are through the dielectric interposer, wherein the conductive structures are electrically connected to the first redistribution layer and the second redistribution layer. Each of the conductive structures has a tapered profile. A width of each of the conductive structures proximal to the first redistribution layer is narrower than a width of each of the conductive structure proximal to the second redistribution layer.

Systems and techniques that facilitate uniform qubit chip gaps via injection-molded solder pillars are provided. In various embodiments, a device can comprise one or more injection-molded solder interconnects. In various aspects, the one or more injection-molded solder interconnects can couple at least one qubit chip to an interposer chip. In various embodiments, the device can further comprise one or more injection-molded solder pillars. In various instances, the one or more injection-molded solder pillars can be between the at least one quit chip and the interposer chip. In various cases, the one or more injection-molded solder pillars can be in parallel with the one or more injection-molded solder interconnects. In various embodiments, the one or more injection-molded solder pillars can facilitate and/or maintain a uniform gap between the at least one qubit chip and the interposer chip. In various embodiments, a melting point of the one or more injection-molded solder pillars can be higher than a melting point of the one or more injection-molded solder interconnects. In various embodiments, the one or more injection-molded solder pillars can be superconductors. In various embodiments, a yield strength of the one or more injection-molded solder pillars can be between 3,000 pounds per square inch and 15,000 pounds per square inch, which can be higher than a yield strength of the one or more injection-molded solder interconnects. In various embodiments, the one or more injection-molded solder pillars can be binary tin alloys, tertiary tin alloys, and/or quaternary tin alloys.

A method of fabricating a semiconductor device is provided. The method includes providing a die stacking unit that includes a plurality of dies stacked on each other, and a plurality of conductive joints connected between each two adjacent dies. The method includes providing a plurality of dummy micro bumps and dummy pads between the two adjacent dies and between the conductive joints. The dummy micro bumps and the dummy pads are connected to one of the two adjacent dies but not to the other, and the dummy micro bumps are formed on some of the dummy pads but not on all of the dummy pads. The method includes dispensing an underfill material into gaps between the plurality of dies, the conductive joints, the dummy micro bumps, and the dummy pads.

A semiconductor device package and a fabrication method thereof are disclosed. The semiconductor package comprises: a package component having a first mounting surface and a second mounting surface; and a first electronic component having a first conductive pad signal communicatively mounted on the first mounting surface through a first type connector; wherein the first type connector comprises a first solder composition having a lower melting point layer sandwiched between a pair of higher melting point layers, wherein the lower melting point layer is composed of alloys capable of forming a room temperature eutectic.

A semiconductor memory device includes a plurality of memory chips that are stacked above one another and connected to each other through a through via, an interface chip that is connected to the plurality of memory chips, and a plurality of first terminals for connection with an external device. The interface chip includes a plurality of second terminals that are connected to the plurality of first terminals, and is capable of receiving a signal that is supplied from the external device through the first and second terminals, and stores configuration information according to which a set number of the second terminals are designated for receiving control signals for the plurality of memory chips.

A semiconductor device includes a wiring substrate having a first surface, a stacked body on the first surface, the stacked body comprising a first chip, a second chip having a through via and positioned between the first chip and the first surface, and a third chip, a first resin contacting the first surface and the third chip, and a second resin sealing the stacked body. The first and second resins are made of different materials.

A semiconductor devise includes a first substrate and a second substrate which are bonded each other. A first substrate includes an insulating first surface film as an uppermost layer, a first electrode and an insulating second surface film respectively formed inside a plurality of openings in the first surface film, and a first seal ring. A second substrate includes an insulating third surface film as an uppermost layer, and a second electrode, an insulating fourth surface film respectively formed inside a plurality of openings in the third surface film, and a second seal ring. The first electrode and the second electrode are directly bonded together. The first surface film and the third surface film are directly bonded together. The second surface film and the fourth surface film are directly bonded together. A seal ring formed of the first seal ring, the second surface film, the fourth surface film, and the second seal ring is continuous between the first substrate and the second substrate.