An embodiment of a memory device may comprise a vertical channel, a first memory cell formed on the vertical channel, a first wordline coupled to the first memory cell, a second memory cell formed on the vertical channel immediately above the first memory cell, a second wordline coupled to the second memory cell, and an airgap disposed between the first wordline and the second wordline. Other embodiments are disclosed and claimed.

Embodiments of three-dimensional (3D) memory devices having through array contacts (TACs) and methods for forming the same are disclosed. In an example, a method for forming a 3D memory device is disclosed. A dielectric stack including interleaved a plurality of dielectric layers and a plurality of sacrificial layers is formed above a substrate. A channel structure extending vertically through the dielectric stack is formed. A first opening extending vertically through the dielectric stack is formed. A spacer is formed in a plurality of shallow recesses and on a sidewall of the first opening. The plurality of shallow recesses abut the sidewall of the first opening. A TAC extending vertically through the dielectric stack is formed by depositing a conductor layer in contact with the spacer in the first opening. A slit extending vertically through the dielectric stack is formed.

Disclosed is a three-dimensional semiconductor memory device including a carbon-containing layer on a substrate, a plurality of electrode interlayer dielectric layers and a plurality of electrode layers that are alternately stacked on the carbon-containing layer, a cell vertical pattern that penetrates at least some of the electrode interlayer dielectric layers and the electrode layers, and a semiconductor pattern between the cell vertical pattern and the carbon-containing layer. The substrate includes a plurality of first grains. The semiconductor pattern includes a plurality of second grains. An average size of the second grains is less than an average size of the first grains.

A semiconductor memory device includes a cell unit including a stack structure and a channel structure penetrating through the stack structure, the stack structure including at least one string selection gate and a plurality of cell gates, cell separation structures separating the cell unit in a first direction, and gate cutting structures defining regions within the cell unit between adjacent cell separation structures. The cell unit includes a first region defined between a first cell separation structure and a first gate cutting structure and a second region defined between the first gate cutting structure and a second gate cutting structure. A ratio of a region of the at least one string selection gate that is occupied by a conductive material in the second region is greater than a ratio of a region of at least one cell gate that is occupied by the conductive material in the second region.

A semiconductor device includes a substrate having a first region and a second region, gate electrodes stacked and spaced apart from each other in a first direction perpendicular to an upper surface of the second substrate, and extending by different lengths in a second direction on the second region to have pad regions in which upper surfaces thereof are exposed, channel structures penetrating the gate electrodes, extending in the first direction, and respectively including a channel layer, on the first region, contact plugs penetrating the pad regions of the gate electrodes and extending in the first direction, and contact insulating layers surrounding the contact plugs. The gate electrodes have side surfaces protruding further toward the contact plugs in the pad regions than ones of the gate electrodes therebelow.

A semiconductor device and a data storage system including the same are provided. The semiconductor device including a plate layer, a pattern structure on the plate layer, an upper pattern layer on the pattern structure, an upper structure including a stack structure and a capping insulating structure covering at least a portion of the stack structure, the stack structure including interlayer insulating layers and gate layers alternately stacked on each other, and separation structures and vertical memory structures penetrating through the upper structure, the upper pattern layer, and the pattern structure, and extending into the plate layer may be provided.

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 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 memory device and a method of manufacturing the memory device includes a stacked structure having a cell region and a slimming region. The memory device also includes a plurality of vertical channel structures each including memory cells and vertically passing through the stacked structure in the cell region. The memory device further includes a plurality of support structures each having a structure of each of the vertical channel structures and vertically passing through the stacked structure in the slimming region. The plurality of support structures have different heights depending on the shape of the stacked structure in the slimming region.