In one embodiment, a semiconductor device includes a first substrate, and a plurality of electrode layers provided above the first substrate and stacked in a first direction. The device further includes a first semiconductor layer extending in the first direction in the plurality of electrode layers, and a metal layer provided above an uppermost one of the plurality of electrode layers and extending to cross the first direction. The device further includes a second semiconductor layer including an impurity diffusion layer that is provided between the first semiconductor layer and the metal layer, electrically connects the first semiconductor layer with the metal layer, and has an impurity concentration higher than an impurity concentration of the first semiconductor layer.

A memory device includes a memory die containing memory elements, a support die containing peripheral devices and bonded to the memory die, and an electrically conductive path between two of the peripheral devices which extends at least partially through the memory die. The electrically conductive path is electrically isolated from the memory elements.

A structure of semiconductor device is provided, including a first circuit structure, formed on a first substrate. A first test pad is disposed on the first substrate. A second circuit structure is formed on a second substrate. A second test pad is disposed on the second substrate. A first bonding pad of the first circuit structure is bonded to a second bonding pad of the second circuit structure. One of the first test pad and the second test pad is an inner pad while another one of the first test pad and the second test pad is an outer pad, wherein the outer pad surrounds the inner pad.

The present invention relates to a power module and a method for manufacturing same, the power module including: a lower ceramic substrate; an upper ceramic substrate which is disposed spaced apart from the upper portion of the lower ceramic substrate, and on the lower surface of which a semiconductor chip is mounted; spacers each having one end bonded to the lower ceramic substrate and the other end bonded to the upper ceramic substrate; first bonding layers each bonding the one end of each spacer to the lower ceramic substrate; and second bonding layers each bonding the other end of each spacer to the upper ceramic substrate. The present invention maintains a constant distance between the lower ceramic substrate and the upper ceramic substrate by having the spacers arranged therebetween, and thus is advantageous in that the semiconductor chip can be protected and heat dissipation efficiency can be increased.

A semiconductor device is provided. The semiconductor device includes a first die, a second die, a first through via, and a second through. The first die includes a first substrate, a first interconnection structure disposed on the first substrate, and a plurality of first bonding substructures over the first interconnect structure. The second die includes a second substrate, a second interconnect structure disposed on the second substrate, and a plurality of second bonding substructures over the second interconnect structure. The plurality of second bonding substructures are bonded to the plurality of first bonding substructures. The first through via and the second through via extend through the second substrate and to the second interconnect structure, wherein the first through via and the second through via are electrically disconnected to each other.

A semiconductor package includes a first wafer comprising a first substrate, a first device structure, and a first bonding layer having a pattern of first bonding pads. The first bonding layer is disposed over the first substrate and the first device structure. The semiconductor package includes a second wafer comprising a second substrate, a second device structure, and a second bonding layer having a pattern of second bonding pads. The second bonding layer is disposed over the first bonding layer. The second device structure is disposed over the second bonding layer. The second substrate is disposed over the second device structure. The first bonding pads are each aligned with a corresponding one of the second bonding pads. The first device structure is electrically coupled to the second device structure, through at least one of the first bonding pads and at least one of the second bonding pads.

Embodiments include semiconductor packages and methods to form the semiconductor packages. A semiconductor package includes a bridge with a hybrid layer on a high-density packaging (HDP) substrate, a plurality of dies over the bridge and the HDP substrate, and a plurality of through mold vias (TMVs) on the HDP substrate. The bridge is coupled between the dies and the HDP substrate. The bridge is directly coupled to two dies of the dies with the hybrid layer, where a top surface of the hybrid layer of the bridge is directly on bottom surfaces of the dies, and where a bottom surface of the bridge is directly on a top surface of the HDP substrate. The TMVs couple the HDP substrate to the dies, and have a thickness that is substantially equal to a thickness of the bridge. The hybrid layer includes conductive pads, surface finish, and/or dielectric.

A memory device and a respective manufacturing method are set forth, wherein the memory device includes: a peripheral circuit layer including a plurality of conductive pads; a bonding structure disposed on the peripheral circuit layer; a cell stack structure disposed on the bonding structure, the cell stack structure including a plurality of gate conductive patterns; and a plurality of vertical gate contact structures respectively connecting the plurality of conductive pads and the plurality of gate conductive patterns while penetrating the bonding structure, wherein each of the plurality of gate conductive patterns includes a first horizontal part and a second horizontal part, which extend horizontally from a cell region to a contact region, and a third horizontal part connected to one end of the first horizontal part and one end of the second horizontal part, the third horizontal part being connected to a corresponding gate contact structure.

A semiconductor package is provided. The semiconductor package includes a first semiconductor substrate, a first semiconductor element layer on an upper surface of the first semiconductor substrate, a first wiring structure on the first semiconductor element layer, a first connecting pad connected to the first wiring structure, a first test pad connected to the first wiring structure, a first front side bonding pad connected to the first connecting pad and including copper (Cu), and a second front side bonding pad connected to the first front side bonding pad and including copper (Cu) which has a nanotwin crystal structure different from a crystal structure of copper (Cu) included in the first front side bonding pad, wherein a width of the first front side bonding pad in the horizontal direction is different from a width of the second front side bonding pad in the horizontal direction.

Microelectronic assemblies fabricated using hybrid manufacturing, as well as related devices and methods, are disclosed herein. As used herein, “hybrid manufacturing” refers to fabricating a microelectronic assembly by arranging together at least two IC structures fabricated by different manufacturers, using different materials, or different manufacturing techniques. For example, a microelectronic assembly may include a first IC structure that includes first interconnects and a second IC structure that includes second interconnects, where at least some of the first and second interconnects may include a liner and an electrically conductive fill material, and where a material composition of the liner/electrically conductive fill material of the first interconnects may be different from a material composition of the liner/electrically conductive fill material of the second interconnects.