A semiconductor device structure and method for manufacturing the same are provided. The semiconductor device structure includes a substrate, a dielectric structure, a pad, a conductive structure, and a buffer structure. The dielectric structure is disposed on the substrate. The pad is embedded in the dielectric structure. The conductive structure is disposed on the pad. The buffer structure is disposed on the pad and separates the conductive structure from the dielectric structure. A coefficient of thermal expansion (CTE) of the buffer structure ranges between a CTE of the dielectric structure and a CTE of the conductive structure.

A semiconductor device structure and method for manufacturing the same are provided. The semiconductor device structure includes a substrate, a dielectric structure, a pad, a conductive structure, and a buffer structure. The dielectric structure is disposed on the substrate. The pad is embedded in the dielectric structure. The conductive structure is disposed on the pad. The buffer structure is disposed on the pad and separates the conductive structure from the dielectric structure. A coefficient of thermal expansion (CTE) of the buffer structure ranges between a CTE of the dielectric structure and a CTE of the conductive structure.

A semiconductor device includes a semiconductor substrate, a metal member, and a metal oxide film. The semiconductor substrate is provided with a through-hole that passes through the semiconductor substrate from one surface to another surface opposite to the one surface. The metal member is provided in the through-hole, and includes a cavity therein defined by an internal surface. The metal oxide film coats the internal surface.

A semiconductor device includes a semiconductor substrate, a metal member, and a metal oxide film. The semiconductor substrate is provided with a through-hole that passes through the semiconductor substrate from one surface to another surface opposite to the one surface. The metal member is provided in the through-hole, and includes a cavity therein defined by an internal surface. The metal oxide film coats the internal surface.

A manufacturing method for a ceramic sintered compact substrate including preparing a ceramic substrate, bonding dry films to a first surface and a second surface of the ceramic substrate, performing exposure and development, performing etching or blasting through the dry films formed into a predetermined pattern, forming a first recessed portion recessed relative to a first flat surface portion of the first surface and a second recessed portion recessed relative to a second flat surface portion of the second surface, peeling off the dry films, disposing a metal paste, and firing the metal paste to obtain a metal member. In the method, before the first recessed portion and the second recessed portion are formed, a through hole penetrating through the ceramic substrate is formed , and the metal paste is disposed in the first recessed portion, the second recessed portion, and the through hole.

Integrated circuit cell architectures including both front-side and back-side structures. One or more of back-side implant, semiconductor deposition, dielectric deposition, metallization, film patterning, and wafer-level layer transfer is integrated with front-side processing. Such double-side processing may entail revealing a back side of structures fabricated from the front-side of a substrate. Host-donor substrate assemblies may be built-up to support and protect front-side structures during back-side processing. Front-side devices, such as FETs, may be modified and/or interconnected during back-side processing. Electrical test may be performed from front and back sides of a workpiece. Back-side devices, such as FETs, may be integrated with front-side devices to expand device functionality, improve performance, or increase device density.

Integrated circuit cell architectures including both front-side and back-side structures. One or more of back-side implant, semiconductor deposition, dielectric deposition, metallization, film patterning, and wafer-level layer transfer is integrated with front-side processing. Such double-side processing may entail revealing a back side of structures fabricated from the front-side of a substrate. Host-donor substrate assemblies may be built-up to support and protect front-side structures during back-side processing. Front-side devices, such as FETs, may be modified and/or interconnected during back-side processing. Electrical test may be performed from front and back sides of a workpiece. Back-side devices, such as FETs, may be integrated with front-side devices to expand device functionality, improve performance, or increase device density.

A device has a first stack of thin films, the first stack of thin films having a first opposing surface and a first connection surface, wherein the first connection surface contacts a first superconducting region; a second stack of thin films, the second stack of thin films having a second opposing surface and a second connection surface, wherein the second connection surface contacts a second superconducting region; and a superconducting bump bond electrically connecting the first and second opposing surfaces, the superconducting bump bond maintaining a low ohmic electrical contact between the first and second opposing surfaces at temperatures below 100 degrees Kelvin, wherein at least one of the first or second superconducting regions comprise material with a melting point of at least 700 degrees Celsius.

A device has a first stack of thin films, the first stack of thin films having a first opposing surface and a first connection surface, wherein the first connection surface contacts a first superconducting region; a second stack of thin films, the second stack of thin films having a second opposing surface and a second connection surface, wherein the second connection surface contacts a second superconducting region; and a superconducting bump bond electrically connecting the first and second opposing surfaces, the superconducting bump bond maintaining a low ohmic electrical contact between the first and second opposing surfaces at temperatures below 100 degrees Kelvin, wherein at least one of the first or second superconducting regions comprise material with a melting point of at least 700 degrees Celsius.

A structure has a first substrate bonded to a first under-bump metallization (UBM) structure, the first UBM structure comprising a first bonding region laterally surrounded by a first superconducting region. A second substrate is bonded to a second under-bump metallization (UBM) structure, the second UBM structure comprising a second bonding region laterally surrounded by a second superconducting region; and a superconducting solder material joins the first UBM structure to the second UBM structure.