Embodiments of a three-dimensional capacitor for a memory device and fabrication methods are disclosed. The method includes forming, on a first side of a first substrate, a peripheral circuitry having a plurality of peripheral devices, a first interconnect layer, a deep well and a first capacitor electrode. The method also includes forming, on a second substrate, a memory array having a plurality of memory cells and a second interconnect layer, and bonding the first interconnect layer of the peripheral circuitry with the second interconnect layer of the memory array. The method further includes forming, on a second side of the first substrate, one or more trenches inside the deep well, disposing a capacitor dielectric layer on sidewalls of the one or more trenches, and forming capacitor contacts on sidewalls of the capacitor dielectric layer inside the one or more trenches.

A wafer-level package structure is provided, including a device wafer integrated with a first chip. The device wafer includes a first front surface integrated with the first chip and a first back surface opposite to the first front surface. A first oxide layer is formed on the first front surface. A second chip is provided to include a bonding surface, on which a second oxide layer is formed. A carrier substrate is provided to be temporarily bonded with the surface of the second chip that faces away from the bonding surface. The second chip is bonded with the device wafer through bonding the first and the second oxide layers using a fusion bonding process. The second chip and the carrier substrate are debonded. An encapsulation layer is formed on the first oxide layer and covers the second chip.

A method for forming a direct hybrid bond and a device resulting from a direct hybrid bond including a first substrate having a first set of metallic bonding pads, preferably connected to a device or circuit, capped by a conductive barrier, and having a first non-metallic region adjacent to the metallic bonding pads on the first substrate, a second substrate having a second set of metallic bonding pads capped by a second conductive barrier, aligned with the first set of metallic bonding pads, preferably connected to a device or circuit, and having a second non-metallic region adjacent to the metallic bonding pads on the second substrate, and a contact-bonded interface between the first and second set of metallic bonding pads capped by conductive barriers formed by contact bonding of the first non-metallic region to the second non-metallic region.

A package structure and method of manufacturing a package structure are provided. The package structure comprises two semiconductor structures and two bonding layers sandwiched between both semiconductor structures. Each bonding layer has a plurality of bonding pads separated by an isolation layer. Each bonding pad has a bonding surface including a bonding region and at least one buffer region. The bonding regions in both bonding layers bond to each other. The buffer region of one semiconductor structure bonds to the isolation layer of the other semiconductor structure. A ratio of a surface area of the buffer region to that of the bonding region in each metal pad is from about 0.01 to about 10.

A semiconductor die stack includes a first semiconductor die having a first lattice direction, and a second semiconductor die bonded to the first semiconductor die and having a second lattice direction different than the first lattice direction.

The present application provides a semiconductor package with air gaps for reducing capacitive coupling between conductive features and a method for manufacturing the semiconductor package. The semiconductor package includes a first semiconductor structure and a second semiconductor structure bonded with the first semiconductor structure. The first semiconductor structure has a first bonding surface. The second semiconductor structure has a second bonding surface partially in contact with the first bonding surface. A portion of the first bonding surface is separated from a portion of the second bonding surface, a space between the portions of the first and second bonding surfaces is sealed and forms an air gap in the semiconductor package.

The present application provides a semiconductor package with air gaps for reducing capacitive coupling between conductive features and a method for manufacturing the semiconductor package. The semiconductor package includes a first semiconductor structure and a second semiconductor structure bonded with the first semiconductor structure. The first semiconductor structure has a first bonding surface. The second semiconductor structure has a second bonding surface partially in contact with the first bonding surface. A portion of the first bonding surface is separated from a portion of the second bonding surface, a space between the portions of the first and second bonding surfaces is sealed and forms an air gap in the semiconductor package.

Semiconductor devices are provided in which a first semiconductor device is bonded to a second semiconductor device. The bonding may occur at a gate level, a gate contact level, a first metallization layer, a middle metallization layer, or a top metallization layer of either the first semiconductor device or the second semiconductor device.

A method of producing a bonded chip stack is described. A first nanofluidic device chip having a first through-wafer via is formed. A second nanofluidic device chip having a second through-wafer via is formed. The first nanofluidic device chip and the second nanofluidic device chip are washed with a detergent solution. A first surface of the first nanofluidic device chip and a second surface of the second nanofluidic device chip are activated by treating the first surface and the second surface with an activation solution. The first nanofluidic device chip and the second nanofluidic device chip are arranged in a stack. The first through-wafer via is aligned with the second through-wafer via in a substantially straight line. The stack of first and second nanofluidic device chips is subjected to annealing conditions.

In a method for connecting components during production of power electronics modules or assemblies, surfaces of the components have a metallic surface layer upon supply, or are furnished therewith, wherein the layer has a surface that is smooth enough to allow direct bonding or is smoothed to obtain a surface that is smooth enough to allow direct bonding. The surface layers of the surfaces that are to be connected are then pressed against each other with a pressure of at least 5 MPa at elevated temperature, so that they are joined to each other, forming a single layer. The method enables simple, rapid connection of even relatively large contact surfaces, which satisfies the high requirements of power electronics modules.