A semiconductor device of the disclosure includes a peripheral circuit structure including a peripheral transistor, a semiconductor layer on the peripheral circuit structure, a source structure on the semiconductor layer, a gate stack structure on the source structure, the gate stack structure including a word line, a gate upper line and a staircase structure, a memory channel structure and a dummy channel structure extending through the gate stack structure, a cut structure extending through the gate upper line, and a bit line overlapping with the memory channel structure. The cut structure includes a narrow section, and a wide section nearer to the staircase structure than the narrow section. A width of the narrow section is less than a width of the wide section.

A thin-film storage transistor includes a charge storage film provided between a channel region and a gate conductor where the charge storage film includes a tunneling dielectric layer formed adjacent the channel region and a charge trapping layer formed adjacent the tunneling dielectric layer. In some embodiments, the charge trapping layer is a layer including silicon, silicon oxide and silicon nitride materials. In one embodiment, the charge trapping layer is a layer including a mixture of silicon, silicon oxide and silicon nitride materials, where the silicon oxide and silicon nitride may or may not be their respective stoichiometric compounds.

The present disclosure may provide a semiconductor device having a stable structure and a low manufacturing degree of the difficulty. The device may include conductive layers and insulating layers which are alternately stacked; a plurality of pillars passing through the conductive layers and the insulating layers; and a plurality of deposition inhibiting patterns, each deposition inhibiting pattern being formed along a portion of an interface between a side-wall of each of the pillars and each of the conductive layers and along a portion of an interface between each of the insulating layers and each of the conductive layers.

Embodiments of 3D memory devices 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 sacrificial layers and dielectric layers is formed above a substrate. A channel structure extending vertically through the dielectric stack is formed. A local dielectric layer is formed on the dielectric stack. A channel local contact opening through the local dielectric layer to expose an upper end of the channel structure, and a slit opening extending vertically through the local dielectric layer and the dielectric stack are simultaneously formed. A memory stack including interleaved conductive layers and the dielectric layers is formed by replacing, through the slit opening, the sacrificial layers with the conductive layers. A channel local contact in the channel local contact opening, and a slit structure in the slit opening are simultaneously formed.

A vertical memory device may include a channel connecting pattern on a substrate, gate electrodes spaced apart from each other in a first direction on the channel connecting pattern, and a channel extending in the first direction through the gate electrodes and the channel connecting pattern. Each of the electrodes may extend in a second direction substantially parallel to an upper surface of the substrate, and the first direction may be substantially perpendicular to the upper surface of the substrate. An end portion of the channel connecting pattern in a third direction substantially parallel to the upper surface of the substrate and substantially perpendicular to the second direction may have an upper surface higher than an upper surface of other portions of the channel connecting pattern except for a portion thereof adjacent the channel.

A method of forming a microelectronic device comprises forming a stack structure comprising vertically alternating insulating structures and additional insulating structures arranged in tiers. Each of the tiers individually comprises one of the insulating structures and one of the additional insulating structures. A first trench is formed to partially vertically extend through the stack structure. The first trench comprises a first portion having a first width, and a second portion at a horizontal boundary of the first portion and having a second width greater than the first width. A dielectric structure is formed within the first trench. The dielectric structure comprises a substantially void-free section proximate the horizontal boundary of the first portion of the trench. Microelectronic devices and electronic systems are also described.

A semiconductor device includes a stack including alternately stacked conductive films and insulating films, wherein the stack includes an opening penetrating the conductive films and the insulating films, and wherein the stack includes a rounded corner that is exposed to the opening. The semiconductor device also includes a first channel film formed in the opening and including a first curved surface surrounding the rounded corner. The semiconductor device further includes a conductive pad formed in the opening, and a second channel film interposed between the first curved surface of the first channel film and the conductive pad.

A 3D semiconductor memory device includes a peripheral circuit structure including a first row decoder region, a second row decoder region, and a control circuit region between the first and second row decoder regions, a first electrode structure and a second electrode structure on the peripheral circuit structure, spaced apart in a first direction, and each including stacked electrodes, a mold structure on the peripheral circuit structure between the first and second electrode structures and including stacked sacrificial layers, vertical channel structures penetrating the first and second electrode structures, a separation insulating pattern provided between the first electrode structure and the mold structure and penetrating the mold structure, and a separation structure intersecting the first electrode structure in the first direction and extending to the separation insulating pattern, wherein a maximum width of the separation insulating pattern in a second direction is greater than a maximum width of the separation structure in the second direction.

A source-level sacrificial layer and an alternating stack of insulating layers and spacer material layers are formed over a substrate. The spacer material layers are formed as, or are subsequently replaced with, electrically conductive layers. Memory openings are formed through the alternating stack and the source-level sacrificial layer, and memory opening fill structures are formed. A source cavity is formed by removing the source-level sacrificial layer, and exposing an outer sidewall of each vertical semiconductor channel in the memory opening fill structures. A metal-containing layer is deposited on physically exposed surfaces of the vertical semiconductor channel and the vertical semiconductor channel is crystallized using metal-induced lateral crystallization. Alternatively or additionally, cylindrical metal-semiconductor alloy regions can be formed around the vertical semiconductor channels to reduce contact resistance. A source contact layer can be formed in the source cavity.

An integrated circuit device includes a substrate, a peripheral wiring circuit that includes a bypass via and is disposed on the substrate, a peripheral circuit that includes an interlayer insulating layer surrounding at least a portion of the peripheral wiring circuit, and a memory cell array disposed on and overlapping the peripheral circuit. The memory cell array includes a base substrate, a plurality of gate lines disposed on the base substrate, and a plurality of channels penetrating the plurality of gate lines. The integrated circuit device further includes a barrier layer interposed between the peripheral circuit and the memory cell array. The barrier layer includes a bypass hole penetrating from a top surface to a lower surface of the barrier layer. The bypass via is disposed in the bypass hole.