A semiconductor device includes a vertical pattern in a first direction, interlayer insulating layers, spaced apart, a side surface of each of the interlayer insulating layers facing a side of the vertical pattern, a gate electrode between the interlayer insulating layers, a side of the gate electrode facing the side of the vertical pattern, a dielectric structure between the vertical pattern and the interlayer insulating layers with the gate electrode between the interlayer insulating layers, and data storage patterns between the gate electrode and the vertical pattern, the data storage patterns spaced apart. The dielectric structure includes a first and a second dielectric layers, the second dielectric layer between the first dielectric layer and the vertical pattern. The data storage patterns are between the first dielectric layer and the second dielectric layer. The first dielectric layer includes portions between the data storage patterns and the gate electrode.

A three-dimensional memory device includes an alternating stack of insulating layers and electrically conductive layers located over a substrate, memory stack structures extending through the alternating stack. Each of the memory stack structures includes a vertical semiconductor channel, a tunneling dielectric layer, and a vertical stack of memory elements located at levels of the electrically conductive layers between a respective vertically neighboring pair of the insulating layers. Each of the memory elements includes a first memory material portion, and a second memory material portion that is vertically spaced from and is electrically isolated from the first memory material portion by at least one blocking dielectric material portion.

A semiconductor memory device according to an embodiment includes a semiconductor substrate; a laminated body formed by laminating a plurality of electrode layers on the semiconductor substrate; a memory film provided in the laminated body and including a first block insulation film disposed in a direction perpendicular to the electrode layer, a charge storage film facing the first block insulation film, a tunnel insulation film facing the charge storage film, and a channel film facing the tunnel insulation film; and a barrier layer provided at at least one of interface between the plurality of electrode layers and the memory film and an interface in the memory film and mainly composed of carbon.

A nonvolatile memory device includes a mold structure including a plurality of insulating patterns and a plurality of gate electrodes alternately stacked on a substrate, a semiconductor pattern penetrating through the mold structure and contacting the substrate, a first charge storage film, and a second charge storage film separated from the first charge storage film. The first and second charge storage films are disposed between each of the gate electrodes and the semiconductor pattern. Each of the gate electrodes includes a first recess and a second recess which are respectively recessed inward from a side surface of the gate electrodes. The first charge storage film fills at least a portion of the first recess, and the second charge storage film fills at least a portion of the second recess.

A 3D memory device, the device including: a first vertical pillar; a second vertical pillar, where the first vertical pillar and the second vertical pillar function as a source or a drain for a plurality of overlaying horizontally-oriented memory transistors, where the plurality of overlaying horizontally-oriented memory transistors are self-aligned being formed following the same lithography step; and memory control circuits, where the memory control circuits are disposed at least partially directly underneath the plurality of overlaying horizontally-oriented memory transistors, or are disposed at least partially directly above the plurality of overlaying horizontally-oriented memory transistors.

A thin-film memory transistor includes a source region, a drain region, a channel region, a gate electrode, and a charge-trapping layer provided between the channel region and the gate electrode and electrically isolated therefrom, wherein the charge-trapping layer has includes a number of charge-trapping sites that is 70% occupied or evacuated using a single voltage pulse of a predetermined width of 500 nanoseconds or less and a magnitude of 15.0 volts or less. The charge-trapping layer comprises silicon-rich nitride may have a refractive index of 2.05 or greater or comprises nano-crystals of germanium (Ge), zirconium oxide (ZrO.sub.2), or zinc oxide (ZnO). The thin-film memory transistor may be implemented, for example, in a 3-dimensional array of NOR memory strings formed above a planar surface of a semiconductor substrate.

The present disclosure, in some embodiments, relates to an integrated chip. The integrated chip includes a source/drain region arranged within a substrate. A first select gate is arranged over the substrate, and a first memory gate is arranged over the substrate and separated from the source/drain region by the first select gate. An inter-gate dielectric structure is arranged between the first memory gate and the first select gate. The inter-gate dielectric structure extends under the first memory gate. A height of the inter-gate dielectric structure decreases along a direction extending from the first select gate to the first memory gate.

Some embodiments include methods of forming semiconductor constructions. Alternating layers of n-type doped material and p-type doped material may be formed. The alternating layers may be patterned into a plurality of vertical columns that are spaced from one another by openings. The openings may be lined with tunnel dielectric, charge-storage material and blocking dielectric. Alternating layers of insulative material and conductive control gate material may be formed within the lined openings. Some embodiments include methods of forming NAND unit cells. Columns of alternating n-type material and p-type material may be formed. The columns may be lined with a layer of tunnel dielectric, a layer of charge-storage material, and a layer of blocking dielectric. Alternating layers of insulative material and conductive control gate material may be formed between the lined columns. Some embodiments include semiconductor constructions, and some embodiments include NAND unit cells.

Some embodiments include methods of forming semiconductor constructions. Alternating layers of n-type doped material and p-type doped material may be formed. The alternating layers may be patterned into a plurality of vertical columns that are spaced from one another by openings. The openings may be lined with tunnel dielectric, charge-storage material and blocking dielectric. Alternating layers of insulative material and conductive control gate material may be formed within the lined openings. Some embodiments include methods of forming NAND unit cells. Columns of alternating n-type material and p-type material may be formed. The columns may be lined with a layer of tunnel dielectric, a layer of charge-storage material, and a layer of blocking dielectric. Alternating layers of insulative material and conductive control gate material may be formed between the lined columns. Some embodiments include semiconductor constructions, and some embodiments include NAND unit cells.

The present disclosure, in some embodiments, relates to a method of forming a memory cell. The method may be performed by forming a sacrificial spacer over a substrate and forming a select gate along a side of the sacrificial spacer. An inter-gate dielectric is formed over the select gate and the sacrificial spacer. A memory gate layer is formed over the inter-gate dielectric and the sacrificial spacer. The memory gate layer is laterally separated from the sacrificial spacer by the select gate. The memory gate layer is etched to define a memory gate having a topmost point below a top of the sacrificial spacer.