A memory opening is formed through a stack of alternating layers comprising first material layers and second material layers. Sidewall surfaces of the second material layers are laterally recessed with respect to sidewall surfaces of the first material layers within the memory opening. Annular semiconductor material portions can be formed by depositing a semiconductor material from the sidewall surfaces of the second material layers while the semiconductor material does not grow from surfaces of the first material layers. Optionally, an inner portion of each annular semiconductor material portion can be converted into an annular dielectric material portion that includes a dielectric material. A memory film is formed in the memory opening. During removal of the second material layers, the annular semiconductor material portions can be employed as an etch stop material, thereby minimizing collateral etching of the memory film or annular dielectric material portions.

A method includes patterning a substrate to form a nanowire over the substrate, applying a plurality of doping processes to the nanowire to form a first drain/source region at a lower portion of the nanowire, a second drain/source region at an upper portion of the nanowire and a channel region, wherein the channel region is between the first drain/source region and the second drain/source region, depositing a first dielectric layer along sidewalls of the channel region, depositing a control gate layer over the first dielectric layer, wherein the control gate layer surrounds a lower portion of the channel region, depositing a second dielectric layer along the sidewalls of the channel region and over the control gate layer and forming a floating gate region surrounding an upper portion of the channel region.

Some embodiments include apparatuses and methods having a substrate, a memory cell string including a body, a select gate located in a level of the apparatus and along a portion of the body, and control gates located in other levels of the apparatus and along other respective portions of the body. At least one of such apparatuses includes a conductive connection coupling the select gate or one of the control gates to a component (e.g., transistor) in the substrate. The connection can include a portion going through a portion of at least one of the control gates.

An approach to use silicided bit line contacts that do not short to the underlying substrate in memory devices. The approach provides for silicide formation in the bit line contact area, using a process that benefits from being self-aligned to the oxide-nitride-oxide (ONO) nitride edges. A further benefit of the approach is that the bit line contact implant and rapid temperature anneal process can be eliminated. This approach is applicable to embedded flash, integrating high density devices and advanced logic processes.

A nonvolatile memory cell includes a first-conductivity-type silicon substrate, a metal layer formed in a surface of the first-conductivity-type silicon substrate, a second-conductivity-type diffusion layer formed in the surface of the first-conductivity-type silicon substrate and spaced apart from the metal layer, an insulating film disposed on the surface of the first-conductivity-type silicon substrate between the metal layer and the second-conductivity-type diffusion layer, a gate electrode disposed on the insulating film between the metal layer and the second-conductivity-type diffusion layer, and a sidewall disposed at a same side of the gate electrode as the metal layer and situated between the gate electrode and the metal layer, the sidewall being made of insulating material.

A semiconductor memory cell includes a floating body region configured to be charged to a level indicative of a state of the memory cell; a first region in electrical contact with said floating body region; a second region in electrical contact with said floating body region and spaced apart from said first region; and a gate positioned between said first and second regions. The cell may be a multi-level cell. Arrays of memory cells are disclosed for making a memory device. Methods of operating memory cells are also provided.

Provided is a semiconductor device including a memory gate structure and a select gate structure. The memory gate structure is closely adjacent to the select gate structure. Besides, an air gap encapsulated by an insulating layer is disposed between the memory gate structure and the select gate structure.

Provided is a semiconductor device having improved performance. In a semiconductor substrate located in a memory cell region, a memory cell of a nonvolatile memory is formed while, in the semiconductor substrate located in a peripheral circuit region, a MISFET is formed. At this time, over the semiconductor substrate located in the memory cell region, a control gate electrode and a memory gate electrode each for the memory cell are formed first. Then, an insulating film is formed so as to cover the control gate electrode and the memory gate electrode. Subsequently, the upper surface of the insulating film is polished to be planarized. Thereafter, a conductive film for the gate electrode of the MISFET is formed and then patterned to form a gate electrode or a dummy gate electrode for the MISFET in the peripheral circuit region.

A semiconductor device includes a semiconductor substrate including a main surface, an element separation film formed over the main surface, and a fin protruding from the element separation film and extending in the first direction in plan view. The semiconductor device further includes a control gate electrode extending in the second direction that is orthogonal to the first direction along the surface of the fin through a gate insulating film and overlaps with a first main surface of the element separation film, and a memory gate electrode extending in the second direction along the surface of the fin through an insulating film and overlaps with a second main surface of the element separation film, in which the second main surface is lower than the first main surface relative to the main surface.

A charge trap memory device is provided. In one embodiment, the charge trap memory device includes a semiconductor material structure having a vertical channel extending from a first diffusion region formed in a semiconducting material to a second diffusion region formed over the first diffusion region, the vertical channel electrically connecting the first diffusion region to the second diffusion region. A tunnel dielectric layer is disposed on the vertical channel, a multi-layer charge-trapping region including a first deuterated layer disposed on the tunnel dielectric layer, a first nitride layer disposed on the first deuterated layer, and a second nitride layer comprising a deuterium-free trap-dense, oxygen-lean nitride disposed on the first nitride layer. The second nitride layer includes a majority of charge traps distributed in the multi-layer charge-trapping region.