A semiconductor device, and method of manufacturing a semiconductor device, includes second conductive patterns separated from each other above a first stack structure which is penetrated by first channel structures and enclosing second channel structures coupled to the first channel structures, respectively. Each of the second conductive patterns includes electrode portions stacked in a first direction and at least one connecting portion extending in the first direction to be coupled to the electrode portions.

According to an embodiment, a non-volatile memory device includes first electrodes stacked on an underlying layer, a second electrode provided on the first electrodes, a semiconductor layer extending in a first direction from the underlying layer to the second electrode, and a memory film provided between each of the first electrodes and the semiconductor layer. The semiconductor layer includes a first portion adjacent to the first electrodes and a second portion adjacent to the second electrode. The second portion has a thickness thinner than a thickness of the first portion in a second direction perpendicular to the first direction.

A semiconductor device includes a semiconductor structure that includes a substrate having a first region and a second region, gate electrodes stacked and spaced apart from each other in a first direction, extend at different lengths in a second direction on the second region, and include pad regions, interlayer insulating layers alternately stacked with the gate electrodes, channel structures penetrating the gate electrodes, extending in the first direction, and each including a channel layer, contact plugs penetrating the pad regions and extending in the first direction on the second region, and contact insulating layers between the gate electrodes and between ones of the contact plugs below the pad regions. The pad regions and the contact insulating layers protrude from the interlayer insulating layers toward the contact plugs in a horizontal direction.

A semiconductor body device includes a stacked body including a plurality of electrode layers stacked with an insulator interposed, a semiconductor body extending in a stacking direction of the stacked body through the electrode layers and having a pipe shape, a plurality of memory cells being provided at intersecting portions of the semiconductor body with the electrode layers, and a columnar insulating member extending in the stacking direction inside the semiconductor body having the pipe shape.

A semiconductor memory device of an embodiment includes: a semiconductor layer extending in a first direction; a gate electrode layer containing at least one element selected from a group consisting of molybdenum (Mo), tungsten (W), ruthenium (Ru), and cobalt (Co); a first insulating layer provided between the semiconductor layer and the gate electrode layer; a charge storage layer provided between the first insulating layer and the gate electrode layer; a second insulating layer provided between the charge storage layer and the gate electrode layer; a third insulating layer provided between the second insulating layer and the gate electrode layer; and a metal oxide layer provided between the third insulating layer and the gate electrode layer and containing at least one first metal element selected from a group consisting of titanium (Ti), molybdenum (Mo), tungsten (W), and tantalum (Ta).

A memory device is provided. The memory device includes a substrate, a fin structure on the substrate, a gate structure on the fin structure, a first source/drain at one end of the fin structure, and a second source/drain at the other end of the fin structure, wherein the gate structure includes a trap layer, a blocking layer, and a gate electrode layer sequentially stacked on the fin structure, the first source/drain is doped with or has incorporated therein dopants of a first conductivity-type, and the second source/drain is doped with or has incorporated therein dopants of a second conductivity-type dopants that are different from the dopants of the first conductivity-type.

Provided is a thin film structure including a substrate, a metal layer on the substrate and spaced apart from the substrate, and a two-dimensional material layer between the substrate and the metal layer. The two-dimensional material layer may be configured to limit and/or block an electron transfer between the substrate and the metal layer. A resistivity of a metal layer on the two-dimensional material layer may be lowered by the two-dimensional material layer.

Some embodiments include methods of forming charge storage transistor gates and standard FET gates in which common processing is utilized for fabrication of at least some portions of the different types of gates. FET and charge storage transistor gate stacks may be formed. The gate stacks may each include a gate material, an insulative material, and a sacrificial material. The sacrificial material is removed from the FET and charge storage transistor gate stacks. The insulative material of the FET gate stacks is etched through. A conductive material is formed over the FET gate stacks and over the charge storage transistor gate stacks. The conductive material physically contacts the gate material of the FET gate stacks, and is separated from the gate material of the charge storage transistor gate stacks by the insulative material remaining in the charge storage transistor gate stacks. Some embodiments include gate structures.

Structures and methods that facilitate the formation of gate contacts for vertical transistors constructed with semiconductor pillars and spacer-like gates are disclosed. In a first embodiment, a gate contact rests on an extended gate region, a piece of a gate film, patterned at a side of a vertical transistor at the bottom of the gate. In a second embodiment, an extended gate region is patterned on top of one or more vertical transistors, resulting in a modified transistor structure. In a third embodiment, a gate contact rests on a top surface of a gate merged between two closely spaced vertical transistors. Optional methods and the resultant intermediate structures are included in the first two embodiments in order to overcome the related topography and ease the photolithography. The third embodiment includes alternatives for isolating the gate contact from the semiconductor pillars or for isolating the affected semiconductor pillars from the substrate.

A semiconductor device may include a gate structure including stacked gate lines, a first contact plug extending through the gate structure, electrically connected to a first gate line among the gate lines, and including a first portion having a taper shape and a second portion having an inverted taper shape, and a second contact plug extending through the gate structure, electrically connected to a second gate line among the gate lines, and having a taper shape.