Embodiments of the present disclosure describe novel qubit device packages, as well as related computing devices and methods. In one embodiment, an exemplary qubit device package includes a qubit die and a package substrate, where the qubit die is coupled to the package substrate using one or more preforms. In particular, a single preform may advantageously be used to replace a plurality of individual contacts, e.g. a plurality of individual solder bumps, electrically coupling the qubit die to the package substrate. Such packages may reduce design complexity and undesired coupling, and enable inclusion of larger numbers of qubits in a single qubit die.

Several embodiments of the present technology are directed to bonding sheets having enhanced plasma resistant characteristics, and being used to bond to semiconductor devices. In some embodiments, a bonding sheet in accordance with the present technology comprises a base bond material having one or more thermal conductivity elements embedded therein, and one or more etched openings formed around particular regions or corresponding features of the adjacent semiconductor components. The bond material can include PDMS, FFKM, or a silicon-based polymer, and the etch resistant components can include PEEK, or PEEK-coated components.

A package structure is provided. The package structure includes a chip-containing structure over a substrate and a first adhesive element directly above the chip-containing structure. The first adhesive element has a first thermal conductivity. The package structure also includes multiple second adhesive elements directly above the chip-containing structure. The second adhesive elements are spaced apart from each other, each of the second adhesive elements has a second thermal conductivity, and the second thermal conductivity is greater than the first thermal conductivity. The package structure further includes a protective lid attached to the chip-containing structure through the first adhesive element and the second adhesive elements. The protective lid extends across opposite sidewalls of the chip-containing structure.

Embodiments of the present disclosure describe novel qubit device packages, as well as related computing devices and methods. In one embodiment, an exemplary qubit device package includes a qubit die and a package substrate, where the qubit die is coupled to the package substrate using one or more preforms. In particular, a single preform may advantageously be used to replace a plurality of individual contacts, e.g. a plurality of individual solder bumps, electrically coupling the qubit die to the package substrate. Such packages may reduce design complexity and undesired coupling, and enable inclusion of larger numbers of qubits in a single qubit die.

A semiconductor package includes a first semiconductor die, an adhesive layer, a second semiconductor die, a plurality of conductive pillars and an encapsulant. The adhesive layer is adhered to the first semiconductor die. The second semiconductor die is stacked over the first semiconductor die. The conductive pillars surround the first semiconductor die. The encapsulant encapsulates the first semiconductor die and the conductive pillars, wherein a top surface of the encapsulant is higher than top surfaces of the conductive pillars

An emissive panel and associated assembly method are provided. The method provides an emissive substrate having an insulating layer with a top surface and a back surface, and a dielectric layer overlying the insulating layer patterned to form a plurality of wells. Each well has a bottom surface formed on the insulating layer top surface with a first electrical interface electrically connected to a first conductive pressure channel (CPC). The CPCs are each made up of a pressure via with sidewalls formed between the well bottom surface and the insulating layer back surface. A metal layer coats the sidewalls, and a medium flow passage formed interior to the metal layer. The method uses negative pressure through the CPCs to help capture emissive elements in a liquid flow deposition process.

A method for bonding a first substrate to a second substrate including the steps of: making contact of a first contact area of the first substrate with a second contact area of the second substrate, which second area is aligned parallel to the first contact area, as a result of which a common contact area is formed; and producing a bond interconnection between the first substrate and the second substrate outside the common contact area. The invention also relates to a corresponding device and a substrate composite of a first substrate and a second substrate, in which a first contact area of the first substrate with a second contact area of the second substrate, which second area is aligned parallel to the first contact area, forms a common contact area, outside the common contact area there being a bond interconnection between the first substrate and the second substrate.

A semiconductor package includes a first semiconductor die, an adhesive layer, a second semiconductor die, a plurality of conductive pillars and an encapsulant. The adhesive layer is adhered to the first semiconductor die. The second semiconductor die is stacked over the first semiconductor die. The conductive pillars surround the first semiconductor die. The encapsulant encapsulates the first semiconductor die and the conductive pillars, wherein a top surface of the encapsulant is higher than top surfaces of the conductive pillars.

This invention discloses a semiconductor package with adhesive material pre-printed on the lead frame and chip, and the manufacturing method. The adhesive material is applied onto the chip carrier and the pin of the lead frame and also on the front electrode of the semiconductor chip via pre-printing. The back of the semiconductor chip is adhered on the chip carrier, and the front electrode of the semiconductor chip and the pin are connected respectively with a metal connector. The size, shape and thickness of the adhesive material are applied according to different application requirements according to size and shapes of the contact zone of the semiconductor chip and the metal connector. Particularly, the adhesive zones are formed by pre-printing the adhesive material thus significantly enhance the quality and performance of semiconductor products, and improves the productivity.

This invention discloses a semiconductor package with adhesive material pre-printed on the lead frame and chip, and the manufacturing method. The adhesive material is applied onto the chip carrier and the pin of the lead frame and also on the front electrode of the semiconductor chip via pre-printing. The back of the semiconductor chip is adhered on the chip carrier, and the front electrode of the semiconductor chip and the pin are connected respectively with a metal connector. The size, shape and thickness of the adhesive material are applied according to different application requirements according to size and shapes of the contact zone of the semiconductor chip and the metal connector. Particularly, the adhesive zones are formed by pre-printing the adhesive material thus significantly enhance the quality and performance of semiconductor products, and improves the productivity.