An electronic device with embedded access to a high-bandwidth, high-capacity fast-access memory includes (a) a memory circuit fabricated on a first semiconductor die, wherein the memory circuit includes numerous modular memory units, each modular memory unit having (i) a three-dimensional array of storage transistors, and (ii) a group of conductors exposed to a surface of the first semiconductor die, the group of conductors being configured for communicating control, address and data signals associated the memory unit; and (b) a logic circuit fabricated on a second semiconductor die, wherein the logic circuit also includes conductors each exposed at a surface of the second semiconductor die, wherein the first and second semiconductor dies are wafer-bonded, such that the conductors exposed at the surface of the first semiconductor die are each electrically connected to a corresponding one of the conductors exposed to the surface of the second semiconductor die. The three-dimensional array of storage transistors may be formed by NOR memory strings.

A stacked die structure includes a base die, a top die and conductive terminals electrically connected to the top die. The base die includes a base semiconductor substrate, a base interconnection layer disposed on the base semiconductor substrate, and a base bonding layer disposed on the base interconnection layer. The top die is stacked on the base die and electrically connected to the base die, wherein the top die includes a top bonding layer, a top semiconductor substrate, a top interconnection layer, top conductive pads and top grounding vias. The top bonding layer is hybrid bonded to the base bonding layer. The top interconnection layer is disposed on the top semiconductor substrate and includes a dielectric layer, conductive layers embedded in the dielectric layer, and conductive vias joining the conductive layers. The conductive pads and top grounding vias are embedded in the dielectric layer and disposed on the conductive layers.

A first semiconductor element according to one embodiment of the present disclosure includes: an element substrate including an element region in which a wiring layer and a first semiconductor layer including a compound semiconductor material are provided as a stack, and a peripheral region outside the element region; a readout circuit substrate opposed to the first semiconductor layer with the wiring layer interposed therebetween, and electrically coupled to the first semiconductor layer with the wiring layer interposed therebetween; a first electrode provided in the wiring layer and electrically coupled to the first semiconductor layer; a second electrode opposed to the first electrode with the first semiconductor layer interposed therebetween; and an insulating layer provided on the second electrode and having a non-reducing property.

A semiconductor package includes a first die, a second die, and an interconnect die coupled to a first plurality of through-die vias in the first die and a second plurality of through-die vias in the second die. The interconnect die provides communications pathways the first die and the second die.

A chip for hybrid bonded interconnect bridging for chiplet integration, the chip comprising: a first chiplet; a second chiplet; an interconnecting die coupled to the first chiplet and the second chiplet through a hybrid bond.

Representative implementations of devices and techniques provide correction for a defective die in a wafer-to-wafer stack or a die stack. A correction die is coupled to a die of the stack with the defective die. The correction die electrically replaces the defective die. Optionally, a dummy die can be coupled to other die stacks of a wafer-to-wafer stack to adjust a height of the stacks.

Embodiments of the present invention provide for the application of strain inducing layers to enhance the mobility of transistors formed on semiconductor-on-insulator (SOI) structures. In one embodiment, a method for fabricating an integrated circuit is disclosed. In a first step, active circuitry is formed in an active layer of a SOI wafer. In a second step, substrate material is removed from a substrate layer disposed on a back side of the SOI wafer. In a third step, insulator material is removed from the back side of the SOI wafer to form an excavated insulator region. In a fourth step, a strain inducing material is deposited on the excavated insulator region. The strain inducing material interacts with the pattern of excavated insulator such that a single layer provides both tensile and compressive stress to p-channel and n-channel transistors, respectively. In alternative embodiments, the entire substrate is removed before forming the strain inducing material.

A method of forming an electrical device is provided that includes forming microprocessor devices on a microprocessor die; forming memory devices on an memory device die; forming component devices on a component die; and forming a plurality of packing devices on a packaging die. Transferring a plurality of each of said microprocessor devices, memory devices, component devices and packaging components to a supporting substrate, wherein the packaging components electrically interconnect the memory devices, component devices and microprocessor devices in individualized groups. Sectioning the supporting substrate to provide said individualized groups of memory devices, component devices and microprocessor devices that are interconnected by a packaging component.

A method includes placing a first package component. The first package component includes a first alignment mark and a first dummy alignment mark. A second package component is aligned to the first package component. The second package component includes a second alignment mark and a second dummy alignment mark. The aligning is performed using the first alignment mark for positioning the first package component, and using the second alignment mark for position the second package component. The second package component is bonded to the first package component to form a package, with the first alignment mark being bonded to the second dummy alignment mark.

The present application discloses a semiconductor device and a method for fabricating the semiconductor device. The semiconductor device includes a first semiconductor structure, a second semiconductor structure, a through semiconductor via, and an insulation layer. The first semiconductor structure includes a first circuit layer and a first main bonding layer in the first circuit layer and substantially coplanar with a front face of the first circuit layer. The second semiconductor structure includes a second circuit layer on the first circuit layer and a second main bonding layer in the second circuit layer, and topologically aligned with and contacted to the first main bonding layer. The through semiconductor via is along the second semiconductor structure and the first and second main bonding layer, and extending to the first circuit layer. The insulation layer is positioned on a sidewall of the through semiconductor via.