A semiconductor device and a method of manufacturing the semiconductor device are provided. The semiconductor device includes a source structure formed on a base, an etch prevention layer formed on the source structure, bit lines, a stack structure located between the etch prevention layer and the bit lines and including conductive layers and insulating layers that are alternately stacked on each other, and a channel structure passing through the stack structure and the etch prevention layer, wherein a lower portion of the channel structure is located in the source structure and a sidewall of the lower portion of the channel structure is in direct contact with the source structure.

The semiconductor device includes a substrate, a stack structure including gate patterns and interlayer insulating films that are alternately stacked on the substrate, an insulating pillar extending in a thickness direction of the substrate within the stack structure, a polycrystalline metal oxide film extending along a sidewall of the insulating pillar between the insulating pillar and the stack structure, a liner film having a transition metal between the insulating pillar and the polycrystalline metal oxide film, and a tunnel insulating film, a charge storage film, and a blocking insulating film which are disposed in order between the polycrystalline metal oxide film and the gate patterns.

A semiconductor memory device includes a substrate including a peripheral circuit; an interconnection array disposed on the peripheral circuit; a cell stack structure disposed on the interconnection array, the cell stack structure including gate electrodes stacked in a vertical direction to form a cell step structure; and a dummy stack structure disposed on the interconnection array, the dummy stack structure including sacrificial layers stacked in the vertical direction to form a dummy step structure parallel to the cell step structure. The interconnection array includes a first lower conductive pattern including a center region overlapping with a slit between the cell step structure and the dummy step structure, a first region extending to overlap with the dummy step structure from the center region, and a second region extending to overlap with the cell step structure from the center region.

Provided is a semiconductor memory device according to an embodiment including: a stacked body including gate electrode layers stacked in a first direction; a semiconductor layer provided in the stacked body and extending in the first direction; and a gate insulating layer provided between the semiconductor layer and at least one of the gate electrode layers, and the gate insulating layer including a first region containing a first oxide including at least one of a hafnium oxide and a zirconium oxide, in which a first length of the at least one of the gate electrode layers in the first direction is larger than a second length of the first region in the first direction.

A semiconductor structure includes a first semiconductor die containing a recesses, and a second semiconductor die which is embedded in the recess in the first semiconductor die and is bonded to the first semiconductor die.

A semiconductor device according to an embodiment includes first and second chips, and a first conductor. The first chip includes a first substrate, a first circuit and a first joint metal. The first circuit is provided on the first substrate. The first joint metal is connected to the first circuit. The second chip includes a second substrate, a second circuit, and a second joint metal. The second substrate includes P-type and N-type well regions. The second circuit is provided on the second substrate and includes a first transistor. The second joint metal is connected to the second circuit and the first joint metal. The first conductor is connected to the N-type well region from a top region of the second chip. The P-type well region is arranged between a gate electrode of the first transistor and the N-type well region.

According to an embodiment, a memory device comprises a conductive layer containing a metal, a semiconductor layer on the conductive layer, electrode layers stacked on the semiconductor layer in a stacking direction, a semiconductor pillar penetrating the electrode layers in the stacking direction and electrically connected to the semiconductor layer, and a charge trap layer between the electrode layers and the semiconductor pillar. The conductive layer has a recess or a through-hole below the semiconductor pillar.

The semiconductor device includes a substrate, a stack structure including gate patterns and interlayer insulating films that are alternately stacked on the substrate, an insulating pillar extending in a thickness direction of the substrate within the stack structure, a polycrystalline metal oxide film extending along a sidewall of the insulating pillar between the insulating pillar and the stack structure, a liner film having a transition metal between the insulating pillar and the polycrystalline metal oxide film, and a tunnel insulating film, a charge storage film, and a blocking insulating film which are disposed in order between the polycrystalline metal oxide film and the gate patterns.

In a MONOS memory of the split-gate type formed by a field effect transistor formed on a fin, it is prevented that the rewrite lifetime of the MONOS memory is reduced due to charges being locally transferred into and out of an ONO film in the vicinity of the top of the fin by repeating the write operation and the erase operation. By forming a source region at a position spaced downward from a first upper surface of the fin in a region directly below a memory gate electrode, the current is prevented from flowing concentratedly at the upper end of the fin.

A semiconductor structure includes a substrate, conductive layers, dielectric layers, an isolation structure, a first memory structure, and a second memory structure. The conductive layers and the dielectric layers are interlaced and stacked on the substrate. The isolation structure is disposed on the substrate and through the conductive layers and the dielectric layers. Each of the first and second memory structures has a radius of curvature. The first and second memory structures penetrate through the conductive layers and the dielectric layers and are disposed on opposite sidewalls of the isolation structure. Each of the first and second memory structures includes protecting structures and a memory structure layer including a memory storage layer. The protecting structures are disposed at two ends of the memory storage layer, and an etching selectivity to the protecting structures is different from an etching selectivity to the memory storage layer.