A semiconductor device has a semiconductor wafer including a plurality of semiconductor die and a plurality of contact pads formed over a first surface of the semiconductor wafer. A trench is formed partially through the first surface of the semiconductor wafer. An insulating material is disposed over the first surface of the semiconductor wafer and into the trench. A conductive layer is formed over the contact pads. The conductive layer can be printed to extend over the insulating material in the trench between adjacent contact pads. A portion of the semiconductor wafer opposite the first surface of the semiconductor wafer is removed to the insulating material in the trench. An insulating layer is formed over a second surface of the semiconductor wafer and side surfaces of the semiconductor wafer. The semiconductor wafer is singulated through the insulating material in the first trench to separate the semiconductor die.

Processing methods may be performed to form a fan-out interconnect structure. The methods may include forming a semiconductor active device structure overlying a first substrate. The semiconductor active device structure may include first conductive contacts. The methods may include forming an interconnect structure overlying a second substrate. The interconnect structure may include second conductive contacts. The methods may also include joining the first substrate with the second substrate. The joining may include coupling the first conductive contacts with the second conductive contacts. The interconnect structure may extend beyond the lateral dimensions of the semiconductor active device structure.

The present disclosure provides an antenna package structure and an antenna packaging method. The package structure includes an antenna circuit chip, a first packaging layer, a first rewiring layer, an antenna structure, a second metal connecting column, a third packaging layer, a second antenna metal layer, and a second metal bump. The antenna circuit chip, the antenna structure, and the second antenna metal layer are interconnected by using the rewiring layer and the metal connecting column.

An apparatus is formed. The apparatus includes a stack of semiconductor chips. The stack of semiconductor chips includes a logic chip and a memory stack, wherein, the logic chip includes at least one of a GPU and CPU. The apparatus also includes a semiconductor chip substrate. The stack of semiconductor chips are mounted on the semiconductor chip substrate. At least one other logic chip is mounted on the semiconductor chip substrate. The semiconductor chip substrate includes wiring to interconnect the stack of semiconductor chips to the at least one other logic chip.

A method of forming a microelectronic device comprises forming a microelectronic device structure comprising a base structure, a doped semiconductive material overlying the base structure, a stack structure overlying the doped semiconductive material, cell pillar structures vertically extending through the stack structure and the doped semiconductive material and into the base structure, and digit line structures vertically overlying the stack structure. An additional microelectronic device structure comprising control logic devices is formed. The microelectronic device structure is attached to the additional microelectronic device structure to form a microelectronic device structure assembly. The base structure and portions of the cell pillar structures vertically extending into the base structure are removed to expose the doped semiconductive material. The doped semiconductive material is then patterned to form at least one source structure over the stack structure and coupled to the cell pillar structures. Microelectronic devices and electronic systems are also described.

An electronic device package includes an encapsulated electronic component, a redistribution layer (RDL) and a conductive via. The RDL is disposed above the encapsulated electronic component. The RDL includes a circuit layer comprising a conductive pad including a pad portion having a curved edge and a center of curvature, and an extension portion protruding from the pad portion and having a curved edge and a center of curvature. The circuit layer further includes a dielectric layer above the RDL. The conductive via is disposed in the dielectric layer and connected to the conductive pad of the RDL. A center of the conductive via is closer to the center of curvature of the edge of the extension portion than to the center of curvature of the edge of the pad portion.

A symmetrical layout technique for an electrostatic discharge ESD device and a corresponding power supply network is presented. The ESD device protects an electronic circuit against an overvoltage or overcurrent and contains a first contact area to establish an electrical contact with a first supply rail, a second contact area to establish an electrical contact with a second supply rail, and a third contact area to establish an electrical contact with a third supply rail. The first and third supply rails provide a first supply voltage, and the second supply rail provides a second supply voltage. Within the ESD device, an axis of symmetry passes through the second contact area, and the first contact area and the third contact area are arranged on opposite sides with regard to the axis of symmetry. The symmetrical layout technique allows flipping the orientation of the ESD device with regard to the supply rails.

A semiconductor package includes a first semiconductor chip comprising a semiconductor substrate and a redistribution pattern on a top surface of the semiconductor substrate, the redistribution pattern having a hole exposing an inner sidewall of the redistribution pattern, a second semiconductor chip on a top surface of the first semiconductor chip, and a bump structure disposed between the first semiconductor chip and the second semiconductor chip. The bump structure is disposed in the hole and is in contact with the inner sidewall of the redistribution pattern.

Three-dimensional integrated circuit component(s) are described including a System-on-a-Chip (SoC) die and a separate static random-access memory (SRAM) subcomponent in a vertically stacked arrangement. Such stacked SoC/SRAM integrated circuit components may form part of a system to render artificial reality images.

A bonded structure is disclosed. The bonded structure can include a first element that includes a first bonding layer, the first bonding layer that has a first contact pad and a routing trace. The routing trace is formed at the same level as the first contact pad. The bonded structure can include a second element that includes a second bonding layer that has a second contact pad. The first element and the second element are directly bonded such that the first contact pad and the second contact pad are directly bonded without an intervening adhesive