The proposed device includes a first chip (102) comprising a superconducting quantum bit and a second chip (104) bonded to the first chip, the second chip including a substrate (108) having first and second opposing surfaces. The first surface (101) facing the first chip includes a layer (105) of superconductor material which includes a first circuit element. The second chip further includes a second layer (107) on the second surface (103) which includes a second circuit element, and a through connector (109) that extends from the first surface to the second surface and electrically connects a portion of the superconductor material layer to the second circuit element.

The proposed device includes a first chip (102) comprising a superconducting quantum bit and a second chip (104) bonded to the first chip, the second chip including a substrate (108) having first and second opposing surfaces. The first surface (101) facing the first chip includes a layer (105) of superconductor material which includes a first circuit element. The second chip further includes a second layer (107) on the second surface (103) which includes a second circuit element, and a through connector (109) that extends from the first surface to the second surface and electrically connects a portion of the superconductor material layer to the second circuit element.

A reversable attachment system includes an adhesion layer, an inter-substrate bond structure, a mating layer and an extension actuator. The adhesion layer is configured to attach to a first substrate. The inter-substrate bond structure is coupled to the adhesion layer. The mating layer is configured to attach to a second substrate. The extension actuator is configured to attach to the second substrate and expand in response to an absorption of a gas. The inter-substrate bond structure is configured to form an initial thermocompression bond with the mating layer in response to an applied pressure and an applied heat. The expansion of the extension actuator in response to absorbing the gas detaches the inter-substrate bond structure from the mating layer.

A cryogenic electronic package includes at least two superconducting and/or conventional metal semiconductor structures. Each of the semiconductor structures includes a substrate and a superconducting trace. Additionally, each of the semiconductor structures includes a passivation layer and one or more under bump metal (UBM) structures. The cryogenic electronic package also includes one or more superconducting and/or conventional metal interconnect structures disposed between selected ones of the at least two superconducting semiconductor structures. The interconnect structures are electrically coupled to respective ones of the UBM structures of the semiconductor structures to form one or more electrical connections between the semiconductor structures. A method of fabricating a cryogenic electronic package is also provided.

A cryogenic electronic package includes at least two superconducting and/or conventional metal semiconductor structures. Each of the semiconductor structures includes a substrate and a superconducting trace. Additionally, each of the semiconductor structures includes a passivation layer and one or more under bump metal (UBM) structures. The cryogenic electronic package also includes one or more superconducting and/or conventional metal interconnect structures disposed between selected ones of the at least two superconducting semiconductor structures. The interconnect structures are electrically coupled to respective ones of the UBM structures of the semiconductor structures to form one or more electrical connections between the semiconductor structures. A method of fabricating a cryogenic electronic package is also provided.

A stacked quantum computing device including a first chip that includes a first dielectric substrate and a superconducting qubit on the first dielectric substrate, and a second chip that is bonded to the first chip and includes a second dielectric substrate, a qubit readout element on the second dielectric substrate, a control wire on the second dielectric substrate, a dielectric layer covering the control wire, and a shielding layer covering the dielectric layer.

A method of manufacturing a bump structure includes forming a passivation layer over a substrate. A metal pad structure is formed over the substrate, wherein the passivation layer surrounds the metal pad structure. A polyimide layer including a polyimide is formed over the passivation layer and the metal pad structure. A metal bump is formed over the metal pad structure and the polyimide layer. The polyimide is a reaction product of a dianhydride and a diamine, wherein at least one of the dianhydride and the diamine comprises one selected from the group consisting of a cycloalkane, a fused ring, a bicycloalkane, a tricycloalkane, a bicycloalkene, a tricycloalkene, a spiroalkane, and a heterocyclic ring.

A semiconductor chip, a display device or an electronic device includes a substrate, one or more conductive pads disposed on the substrate, and one or more bumps electrically connected to the one or more conductive pads, in which the one or more bumps includes a metal core, a polymer layer disposed over a surface of the metal core, and a conductive coating layer disposed over a surface of the polymer layer and electrically connected to the one or more conductive pads.

A semiconductor chip, a display device or an electronic device includes a substrate, one or more conductive pads disposed on the substrate, and one or more bumps electrically connected to the one or more conductive pads, in which the one or more bumps includes a metal core, a polymer layer disposed over a surface of the metal core, and a conductive coating layer disposed over a surface of the polymer layer and electrically connected to the one or more conductive pads.

A device (100) includes a first chip (104) having a first circuit element (112), a first interconnect pad (116) in electrical contact (118) with the first circuit element, and a barrier layer (120) on the first interconnect pad, a superconducting bump bond (106) on the barrier layer, and a second chip (102) joined to the first chip by the superconducting bump bond, the second chip having a quantum circuit element (108), in which the superconducting bump bond provides an electrical connection between the first circuit element and the quantum circuit element.