A metal oxide semiconductor field effect transistors (MOSFET) memory array, including a complementary metal oxide semiconductor (CMOS) cell including an n-type MOSFET having a modified gate dielectric; and an n-type or p-type MOSFET having an unmodified gate dielectric layer, where the modified gate dielectric layer incorporates an oxygen scavenging species.

A memory structure, includes (a) active columns of polysilicon formed above a semiconductor substrate, each active column extending vertically from the substrate and including a first heavily doped region, a second heavily doped region, and one or more lightly doped regions each adjacent both the first and second heavily doped region, wherein the active columns are arranged in a two-dimensional array extending in second and third directions parallel to the planar surface of the semiconductor substrate; (b) charge-trapping material provided over one or more surfaces of each active column; and (c) conductors each extending lengthwise along the third direction. The active columns, the charge-trapping material and the conductors together form a plurality of thin film transistors, with each thin film transistor formed by one of the conductors, a portion of the lightly doped region of an active column, the charge-trapping material between the portion of the lightly doped region and the conductor, and the first and second heavily doped regions. The thin film transistors associated with each active column are organized into one or more vertical NOR strings.

A method of manufacturing a memory device includes providing a semiconductor substrate including a first region and a second region. The method includes forming a lower structure including interconnect lines and an etch stop layer in the second region. The method includes forming a multilayer structure on the lower structure. The method also includes forming a slit trench in the multilayer structure of the first region, a first plug hole exposing the etch stop layer of the second region therethrough, and a second plug hole exposing a portion of the interconnect lines of the second region therethrough.

A memory is described. Generally, the memory includes a number of non-planar multigate transistors, each including a channel of semiconducting material overlying a surface of a substrate and electrically connecting a source and a drain, a tunnel dielectric layer overlying the channel on at least three sides thereof, and a multi-layer charge-trapping region overlying the tunnel dielectric layer. In one embodiment, the multi-layer charge-trapping region includes a first deuterated layer overlying the tunnel dielectric layer and a first nitride-containing layer overlying the first deuterated layer. Other embodiments are also described.

Various embodiments comprise apparatuses and methods, such as a memory stack having a continuous cell pillar. In various embodiments, the apparatus includes a source material, a buffer material, a select gate drain (SGD), and a memory stack arranged between the source material and the SGD. The memory stack comprises alternating levels of conductor materials and dielectric materials. A continuous channel-fill material forms a cell pillar that is continuous from the source material to at least a level corresponding to the SGD.

A semiconductor device includes memory blocks each configured to comprise a pair of channels, each channel including a pipe channel formed in a pipe gate of the memory block and a drain-side channel and a source-side channel coupled to the pipe channel; first slits placed between the memory blocks adjacent to other memory blocks; and a second slit placed between the source-side channel and the drain-side channel of each pair of channels.

Deterioration in reliability is prevented regarding a semiconductor device. The deterioration is caused when an insulating film for formation of a sidewall is embedded between gate electrodes at the time of forming sidewalls having two kinds of different widths on a substrate. A sidewall-shaped silicon oxide film is formed over each sidewall of a gate electrode of a low breakdown voltage MISFET and a pattern including a control gate electrode and a memory gate electrode. Then, a silicon oxide film beside the gate electrode is removed, and a silicon oxide film is formed on a semiconductor substrate, and then etchback is performed. Accordingly, a sidewall, formed of a silicon nitride film and the silicon oxide film, is formed beside the gate electrode, and a sidewall, formed of the silicon nitride film and the silicon oxide films, is formed beside the pattern.

Techniques for fabricating a memory device which has reduced neighboring word line interference, and a corresponding memory device. The memory device comprises a stack of alternating conductive and dielectric layers, where the conductive layers form word lines or control gates of memory cells. In one aspect, the memory device is provided with a reduced dielectric constant (k) in locations of a fringing electric field of the control gate. For example, portions of the dielectric layers can be replaced with a low-k material. One approach involves recessing the dielectric layer and providing a low-k material in the recess. Another approach involves doping a portion of the blocking oxide layer to reduce its dielectric constant. Another approach involves removing a portion of the blocking oxide layer. In another aspect, the memory device is provided with an increased dielectric constant adjacent to the control gates.

A method of making a monolithic three dimensional NAND string is provided. A stack of alternating layers of a first material and a second material different from the first material is formed over a substrate. The stack is etched to form at least one opening in the stack. A charge storage material layer is formed on a sidewall of the at least one opening. A tunnel dielectric layer is formed on the charge storage material layer in the at least one opening. A semiconductor channel material is formed on the tunnel dielectric layer in the at least one opening. The first material layers are selectively removed to expose side wall of the charge storage material layer. A blocking dielectric is formed on the exposed side wall of the charge storage material layer. Control gates are formed on the blocking dielectric.

Provided is a semiconductor device having improved performance. Over a semiconductor substrate, a dummy control gate electrode is formed via a first insulating film. Over the semiconductor substrate, a memory gate electrode for a memory cell is formed via a second insulating film having an internal charge storage portion so as to be adjacent to the dummy control gate electrode. At this time, the height of the memory gate electrode is adjusted to be lower than the height of the dummy control gate electrode. Then, a third insulating film is formed so as to cover the dummy control gate electrode and the memory gate electrode. Then, the third insulating film is polished to expose the dummy control gate electrode. At this time, the memory gate electrode is not exposed. Then, the dummy control gate electrode is removed and replaced with a metal gate electrode.