A wafer bonding apparatus includes lower and upper stages, lower and upper push rods, a position detection sensor, and processing circuitry. The stages may vacuum suction respective wafers on respective surfaces of the stages based on a vacuum pressure being supplied to respective suction holes in the respective surfaces from a vacuum pump. The push rods are movable through respective center holes in the stages to apply pressure to respective middle regions of the respective wafers. The position detection sensor may generate information indicating a bonding propagation position of the wafers based on detecting at least one wafer through a detection hole in at least one stage. The processing circuitry may process the information to detect the bonding propagation position and cause a change of at least one of a ratio of protruding lengths of the push rods, or a ratio of suction areas of the stages.

A wafer bonding apparatus includes lower and upper stages, lower and upper push rods, a position detection sensor, and processing circuitry. The stages may vacuum suction respective wafers on respective surfaces of the stages based on a vacuum pressure being supplied to respective suction holes in the respective surfaces from a vacuum pump. The push rods are movable through respective center holes in the stages to apply pressure to respective middle regions of the respective wafers. The position detection sensor may generate information indicating a bonding propagation position of the wafers based on detecting at least one wafer through a detection hole in at least one stage. The processing circuitry may process the information to detect the bonding propagation position and cause a change of at least one of a ratio of protruding lengths of the push rods, or a ratio of suction areas of the stages.

A semiconductor device and method of manufacture are provided wherein semiconductor devices are attached over a semiconductor substrate. An opening is formed within metallization layers over the semiconductor substrate and the semiconductor substrate, and an encapsulant is placed to fill the opening. Once the encapsulant is placed, the semiconductor substrate is singulated to separate the devices. By recessing the material of the metallization layers and forming the opening, delamination damage may be reduced or eliminated.

Embodiments of 3D memory devices and methods for forming the same are disclosed. In an example, a method for forming a 3D memory device is disclosed. A peripheral circuit is formed on a first substrate. A first semiconductor layer is formed on a second substrate. A supporting structure and a second semiconductor layer coplanar with the supporting structure are formed on the first semiconductor layer. A memory stack is formed above the supporting structure and the second semiconductor layer. The memory stack has a staircase region overlapping the supporting structure. A channel structure extending vertically through the memory stack and the second semiconductor layer into the first semiconductor layer is formed. The first substrate and the second substrate are bonded in a face-to-face manner.

A microelectronic structure with through substrate vias (TSVs) and method for forming the same is disclosed. The microelectronic structure can include a bulk semiconductor with a via structure. The via structure can have a first and second conductive portion. The via structure can also have a barrier layer between the first conductive portion and the bulk semiconductor. The structure can have a second barrier layer between the first and second conductive portions. The second conductive portion can extend from the second barrier layer to the upper surface of the bulk semiconductor. The microelectronic structure containing TSVs is configured so that the microelectronic structure can be bonded to a second element or structure.

Some implementations described herein provide a semiconductor structure. The semiconductor structure includes a first conductive structure disposed within a first layer of the semiconductor structure. The semiconductor structure includes a dielectric structure disposed within a second layer of the semiconductor structure, with the second layer being disposed on the first layer. The semiconductor structure includes a second conductive structure disposed within a recessed portion of the dielectric structure that extends to the first conductive structure, with the second conductive structure having a concave recessed portion on a top surface of the second conductive structure. The semiconductor structure includes multiple layers of conductive material disposed within the concave recessed portion of the second conductive structure.

Embodiments relate to using nanoporous metal tips to establish connections between a first body and a second body. The first body is positioned relative to the second body to align contacts protruding from a first surface of the first body with electrodes protruding from a second surface of the second body. The second surface faces the first surface. The contacts, the electrodes, or both comprise nanoporous metal tips. A relative movement is made between the first body and the second body after positioning the first body to approach the first body to the second body. The contacts and the electrodes are bonded by melting and solidifying the nanoporous metal tips after approaching the first body and the second body.

A method for wafer bonding includes receiving a layout of a bonding layer with an asymmetric pattern, determining whether an asymmetry level of the layout is within a predetermined range by a design rule checker, modifying the layout to reduce the asymmetry level of the layout if the asymmetry level is beyond the predetermined range. The method also includes outputting the layout in a computer-readable format.

A package includes silicon waveguides on a first side of an oxide layer; photonic devices on the first side of the oxide layer, wherein the photonic devices are coupled to the silicon waveguides; redistribution structures over the first side of the oxide layer, wherein the redistribution structures are electrically connected to the photonic devices; a hybrid interconnect structure on a second side of the oxide layer, wherein the hybrid interconnect structure includes a stack of silicon nitride waveguides that are separated by dielectric layers; and through vias extending through the hybrid interconnect structure and the oxide layer, wherein the through vias make physical and electrical connection to the redistribution structures.

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 to of the first and second bonding surfaces is sealed and forms an air gap in the semiconductor package.