A semiconductor device includes a memory cell region positioned on a substrate and comprising a real memory cell region and a dummy memory cell region; and a connection region extending in a first direction parallel to a surface of the substrate in the memory cell region. The dummy memory cell region includes a plurality of dummy vertical channel structures spaced apart from each other. Each of the plurality of dummy vertical channel structures includes a vertical channel pattern in contact with the substrate while penetrating a stack structure comprising a plurality of insulating layers and a plurality of gate electrodes repeatedly stacked in a third direction perpendicular to a surface of the substrate. A protection pattern is disposed to surround the vertical channel pattern of at least one of the plurality of dummy vertical channel structures.

A vertical memory device may include a first conductive line structure and an address decoder. The first conductive line structure may be on a substrate. The first conductive line structure may include conductive lines and insulation layers alternately and repeatedly stacked in a direction perpendicular to the substrate. The address decoder may be connected to a first end of each of conductive lines included in the first conductive line structure. The address decoder may apply electrical signal to the conductive lines. In each of the conductive lines, a first portion adjacent to the first end and a second portion adjacent to a second end may have different shapes. A first resistance in the first portion may be lower than a second resistance in the second portion. RC delay of the conductive lines may be reduced.

A semiconductor memory device includes: a stacked structure including first layers including conductive layers disposed in a first and a third regions and insulating layers disposed in a second region, first to third insulating members extending in a stacking direction, semiconductor layers disposed in the first and the third regions, and a contact electrode disposed in the second region. The first and the third insulating members extend across the first to third regions and the second insulating member extends across the first and the third regions. The second insulating member contacts the insulating layers. The first layers extend in a direction in the second region from a side of the first insulating member to a side of the third insulating member. The conductive layers in the first and the third regions are mutually connected via conductive layers in the second region.

A three-dimensional memory device includes an alternating stack of insulating layers and electrically conductive layers, memory openings vertically extending through the alternating stack, and memory opening fill structures located within the memory openings. Each of the electrically conductive layers includes a metallic fill material layer and a plurality of vertical tubular metallic liners laterally surrounding a respective one of the memory opening fill structures and located between the metallic fill material layer and a respective one of the memory opening fill structures. The tubular metallic liners may be formed by selective metal or metal oxide deposition, or by conversion of surface portions of the metallic fill material layers into metallic compound material portions by nitridation, oxidation, or incorporation of boron atoms.

A semiconductor memory device according to an embodiment includes: a first conductive layer; a stacked body including a plurality of second conductive layers and a plurality of first insulating layers alternately stacked one by one above the first conductive layer, and including a stepped portion in which the plurality of second conductive layers is terraced; and a plate-like portion including a third conductive layer that extends in the stacked body from the stepped portion to a memory region continuously in a stacking direction and in a first direction, the plate-like portion dividing the stacked body in a second direction that crosses both the stacking direction and the first direction. The plate-like portion includes, in the stepped portion, a plurality of contact portions that is arranged intermittently in the first direction, the plurality of contact portions penetrating the stacked body and connecting with the first conductive layer.

A vertical layer stack including a bit-line-level dielectric layer and an etch stop dielectric layer can be formed over an array region. Bit-line trenches are formed through the vertical layer stack. Bit-line-trench fill structures are formed in the bit-line trenches. Each of the bit-line-trench fill structures includes a stack of a bit line and a capping dielectric strip. At least one via-level dielectric layer can be formed over the vertical layer stack. A bit-line-contact via cavity can be formed through the at least one via-level dielectric layer and one of the capping dielectric strips. A bit-line-contact via structure formed in the bit-line-contact via cavity includes a stepped bottom surface including a top surface of one of the bit lines, a sidewall segment of the etch stop dielectric layer, and a segment of a top surface of the etch stop dielectric layer.

A semiconductor memory device and a method of manufacturing the semiconductor memory device are provided. The semiconductor memory device includes a gate stacked structure with a cell array region and a contact region with a stepped shape, and a roughness of a first sidewall of the cell array region is greater than that of a second sidewall of the contact region.

A bonded assembly includes a memory die that is bonded to a logic die. The memory die includes a three-dimensional memory array located on a memory-side substrate, memory-side dielectric material layers located on the three-dimensional memory array and embedding memory-side metal interconnect structures and memory-side bonding pads, a backside peripheral circuit located on a backside surface of the memory-side substrate, and backside dielectric material layers located on a backside of the memory-side substrate and embedding backside metal interconnect structures. The logic die includes a logic-side peripheral circuit located on a logic-side substrate, and logic-side dielectric material layers located between the logic-side substrate and the memory die and embedding logic-side metal interconnect structures and logic-side bonding pads that are bonded to a respective one of the memory-side bonding pads.

Embodiments of through array contact structures of a 3D memory device and fabricating method thereof are disclosed. The memory device includes an alternating layer stack disposed on a first substrate. The alternating layer stack includes a first region including an alternating dielectric stack, and a second region including an alternating conductor/dielectric stack. The memory device further comprises a barrier structure including two parallel barrier walls extending vertically through the alternating layer stack and laterally along a word line direction to laterally separate the first region from the second region. The memory device further comprises a plurality of through array contacts in the first region, each through array contact extending vertically through the alternating dielectric stack.

A three-dimensional (3D) semiconductor memory device includes a peripheral logic structure disposed on a first substrate, a horizontal semiconductor layer disposed on a second substrate, a plurality of stack structures on the horizontal semiconductor layer in a first direction, wherein the plurality of stack structures include a memory cell region and a capacitor region, a plurality of electrode isolation regions extending in the first direction and a second direction and configured to separate the plurality of stack structures to be connected to the horizontal semiconductor layer and a plurality of through-via structures having a first side connected to a through channel contact through at least one metal pad, wherein a capacitor is formed between each of electrode pads and at least one of electrode isolation regions in the plurality of stack structures or at least one of the plurality of through-via structures.