In an embodiment, a method includes performing a first plasma deposition to form a buffer layer over a first side of a first integrated circuit device, the first integrated circuit device comprising a first substrate and a first interconnect structure; performing a second plasma deposition to form a first bonding layer over the buffer layer, wherein a plasma power applied during the second plasma deposition is greater than a plasma power applied during the first plasma deposition; planarizing the first bonding layer; forming a second bonding layer over a second substrate; pressing the second bonding layer onto the first bonding layer; and removing the first s

A fingerprint sensor device and a method of making a fingerprint sensor device. As non-limiting examples, various aspects of this disclosure provide various fingerprint sensor devices, and methods of manufacturing thereof, that comprise a sensing area on a bottom side of a die without top side electrodes that senses fingerprints from the top side, and/or that comprise a sensor die directly electrically connected to conductive elements of a plate through which fingerprints are sensed.

Structures and methods of fabricating semiconductor wafer assemblies that encapsulate one or die in a cavity etched into an oxide bonded semiconductor wafer stack. The methods generally include the steps of positioning the die in the cavity, mechanically and electrically mounting the die to the wafer stack, and encapsulating the die within the cavity by bonding a lid wafer to the wafer stack in one of multiple ways. Semiconductor processing steps are applied to construct the assemblies (e.g., deposition, annealing, chemical and mechanical polishing, etching, etc.) and connecting the die (e.g., bump bonding, wire interconnecting, ultrasonic bonding, oxide bonding, etc.) according to the embodiments described above.

Structures and methods of fabricating semiconductor wafer assemblies that encapsulate one or die in a cavity etched into an oxide bonded semiconductor wafer stack. The methods generally include the steps of positioning the die in the cavity, mechanically and electrically mounting the die to the wafer stack, and encapsulating the die within the cavity by bonding a lid wafer to the wafer stack in one of multiple ways. Semiconductor processing steps are applied to construct the assemblies (e.g., deposition, annealing, chemical and mechanical polishing, etching, etc.) and connecting the die (e.g., bump bonding, wire interconnecting, ultrasonic bonding, oxide bonding, etc.) according to the embodiments described above.

Techniques facilitating three-dimensional stacked vertical transport field effect transistor logic gates with buried power bus are provided. A logic device can comprise a plate and a first vertical transport field effect transistor formed over and adjacent the plate. The logic device can also comprise a second vertical transport field effect transistor stacked on the first vertical transport field effect transistor. The plate can be a power layer and can be continuous within regions of the device that utilize a common voltage. The plate can be contacted from a surface of the device at intervals corresponding to the regions of common voltage. The plate can be electrically connected to ground. Alternatively, the plate can be electrically connected to a power supply.

Techniques facilitating three-dimensional stacked vertical transport field effect transistor logic gates with buried power bus are provided. A logic device can comprise a plate and a first vertical transport field effect transistor formed over and adjacent the plate. The logic device can also comprise a second vertical transport field effect transistor stacked on the first vertical transport field effect transistor. The plate can be a power layer and can be continuous within regions of the device that utilize a common voltage. The plate can be contacted from a surface of the device at intervals corresponding to the regions of common voltage. The plate can be electrically connected to ground. Alternatively, the plate can be electrically connected to a power supply.

Techniques facilitating three-dimensional stacked vertical transport field effect transistor logic gates with buried power bus are provided. A logic device can comprise a plate and a first vertical transport field effect transistor formed over and adjacent the plate. The logic device can also comprise a second vertical transport field effect transistor stacked on the first vertical transport field effect transistor. The plate can be a power layer and can be continuous within regions of the device that utilize a common voltage. The plate can be contacted from a surface of the device at intervals corresponding to the regions of common voltage. The plate can be electrically connected to ground. Alternatively, the plate can be electrically connected to a power supply.

A nitride-based semiconductor device includes a nitride-based semiconductor wafer, a protecting layer, and a plurality of connecting bumps. The nitride-based semiconductor wafer comprises a plurality of nitride-based dies. Each of the nitride-based dies comprises a connecting surface and a plurality of connecting pads and the connecting pads are embedded in the connecting surface. The protecting layer is disposed on the connecting surfaces of the nitride-based dies. The connecting bumps are embedded in the protecting layer. Every connecting bump connects one of the connecting pads. Every connecting bump has a first polished plane, and the first polished plane is free from the protecting layer. A manufacturing method of nitride-based semiconductor device is also provided.

A semiconductor device includes a metal chip mounting member and a semiconductor chip bonded to the chip mounting member through a metal sintered material, wherein the metal sintered material includes a first portion overlapping the semiconductor chip in a plan view, and includes a second portion surrounding the semiconductor chip in the plan view, and wherein a porosity ratio of the first portion is greater than or equal to 1% and less than 15%, and a porosity ratio of the second portion is greater than or equal to 15% and less than or equal to 50%.

A fingerprint sensor device and a method of making a fingerprint sensor device. As non-limiting examples, various aspects of this disclosure provide various fingerprint sensor devices, and methods of manufacturing thereof, that comprise a sensing area on a bottom side of a die without top side electrodes that senses fingerprints from the top side, and/or that comprise a sensor die directly electrically connected to conductive elements of a plate through which fingerprints are sensed.