Embodiments of the present invention disclose a computer system having a plurality of quantum circuits arranged in a two-dimensional plane-like structure, the quantum circuits comprising qubits and busses (i.e., qubit-qubit interconnects), and a method of formation therefor. A quantum computer system comprises a plurality of quantum circuits arranged in a two-dimensional pattern. At least one interior quantum circuit, not along the perimeter of the two-dimensional plane of the plurality of quantum circuits, contains a bottom chip, a device layer, a top chip, and a routing layer. A signal wire connects the device layer to the routing layer, wherein the signal wire breaks the two dimensional plane, for example, the signal wire extends into a different plane.

Implementations described herein relate to various semiconductor device assemblies. In some implementations, a semiconductor device assembly may include a substrate including multiple first electrical contacts and multiple bondable pillars. In some implementations, each bondable pillar, of the multiple bondable pillars, may be coupled to a corresponding first electrical contact, of the multiple first electrical contacts. The semiconductor device assembly may further include one or more dies coupled to the substrate and including multiple second electrical contacts. In some implementations, the semiconductor device assembly may include multiple wire bonds, with each wire bond, of the multiple wire bonds, bonding a second electrical contact, of the multiple second electrical contacts, to a bondable pillar, of the multiple bondable pillars.

Flexible interconnects, flexible integrated circuit systems and devices, and methods of making and using flexible integrated circuitry are presented herein. A flexible integrated circuit system is disclosed which includes first and second discrete devices that are electrically connected by a discrete flexible interconnect. The first discrete devices includes a first flexible multi-layer integrated circuit (IC) package with a first electrical connection pad on an outer surface thereof. The second discrete device includes a second flexible multi-layer integrated circuit (IC) package with a second electrical connection pad on an outer surface thereof. The discrete flexible interconnect is attached to and electrically connects the first electrical connection pad of the first discrete device to the second electrical connection pad of the second discrete device.

Flexible interconnects, flexible integrated circuit systems and devices, and methods of making and using flexible integrated circuitry are presented herein. A flexible integrated circuit system is disclosed which includes first and second discrete devices that are electrically connected by a discrete flexible interconnect. The first discrete devices includes a first flexible multi-layer integrated circuit (IC) package with a first electrical connection pad on an outer surface thereof. The second discrete device includes a second flexible multi-layer integrated circuit (IC) package with a second electrical connection pad on an outer surface thereof. The discrete flexible interconnect is attached to and electrically connects the first electrical connection pad of the first discrete device to the second electrical connection pad of the second discrete device.

A chip package structure and a method for producing the same are provided. The method at least includes: providing a substrate; forming a mirror ink on the substrate; placing a chip upside-down on the substrate; forming soldering wires coupled with the chip and the substrate; forming a support body on the substrate; providing a package cover adhered to a top surface of the support body; performing a solidifying process in which a solidifying light beam is emitted to the mirror ink and the mirror ink reflects the solidifying light beam to the support body to solidify the support body; performing a packaging process in which a package layer is formed to cover the chip, an outer periphery of the support body, and the package cover; and performing a cutting process in which the package layer and the substrate are cut to form the chip package structure.

A method of forming an electrical contact is provided. The method may include depositing, by atomic layer deposition, a passivation layer over at least a region of a metal surface, wherein the passivation layer may include aluminum oxide, and electrically contacting the region of the metal surface with a metal contact structure, wherein the metal contact structure may include copper.

Generally discussed herein are systems and methods that can include a stretchable and bendable device. According to an example a method can include (1) depositing a first elastomer material on a panel, (2) laminating trace material on the elastomer material, (3) processing the trace material to pattern the trace material into one or more traces and one or more bond pads, (4) attaching a die to the one or more bond pads, or (5) depositing a second elastomer material on and around the one or more traces, the bonds pads, and the die to encapsulate the one or more traces and the one or more bond pads in the first and second elastomer materials.

A disclosed circuit arrangement includes a flexible substrate. A layer of pressure sensitive adhesive (PSA) is directly adhered to a first major surface of the substrate. One or more metal foil pads and electrically conductive wire are attached directly on a surface of the PSA layer. The wire has a round cross-section and one or more portions directly connected to the one or more metal foil pads with one or more weld joints, respectively. An electronic device is attached directly on the surface of the layer of PSA and is electrically connected to the one or more portions of the round wire by one or more bond wires, respectively.

An integrated circuit and method of making an integrated circuit is provided. The integrated circuit includes an electrically conductive pad having a generally planar top surface that includes a cavity having a bottom surface and sidewalls extending from the bottom surface of the cavity to the top surface of the pad. An electronic device is attached to the top surface of the electrically conductive pad. A wire bond is attached from the electronic device to the bottom surface of the cavity. A molding compound encapsulates the electronic device.

An exemplary semiconductor device can comprise a die, a redistribution structure (RDS), an interconnect, a conductive strap, an encapsulant, and an EMI shield. The redistribution structure can comprise an RDS top surface coupled to the die bottom side. The interconnect can be coupled to the RDS bottom surface. The conductive strap can be coupled to the RDS, and can comprise a strap inner end coupled to the RDS bottom surface, and a strap outer end located lower than the RDS bottom surface. The encapsulant can encapsulate the conductive strap and the RDS bottom surface. The EMI shield can cover and contact the encapsulant sidewall and the strap outer end. Other examples and related methods are also disclosed herein.