Disclosed herein is a semiconductor device comprising a first dielectric disposed over a channel region of a transistor formed in a substrate and a gate disposed over the first dielectric. The semiconductor device further includes a second dielectric disposed vertically, substantially perpendicular to the substrate, at an edge of the gate, and a spacer disposed proximate to the second dielectric. The spacer includes across-section with a perimeter that includes atop curved portion and a vertical portion substantially perpendicular to the substrate. The perimeter further includes a discontinuity at an interface of the top curved portion with the vertical portion. Further, disclosed herein are methods associated with the fabrication of the aforementioned semiconductor device.

In a vertical-type memory device and a method of manufacturing the vertical-type memory device, the vertical memory device includes an insulation layer pattern of a linear shape provided on a substrate, pillar-shaped single-crystalline semiconductor patterns provided on both sidewalls of the insulation layer pattern and transistors provided on a sidewall of each of the single-crystalline semiconductor patterns. The transistors are arranged in a vertical direction of the single-crystalline semiconductor pattern, and thus the memory device may be highly integrated.

A semiconductor switching device includes a first load terminal electrically connected to source zones of transistor cells. The source zones form first pn junctions with body zones. A second load terminal is electrically connected to a drain construction that forms second pn junctions with the body zones. Control structures, which include a control electrode and charge storage structures, directly adjoin the body zones. The control electrode controls a load current through the body zones. The charge storage structures insulate the control electrode from the body zones and contain a control charge adapted to induce inversion channels in the body zones in the absence of a potential difference between the control electrode and the first load electrode.

A non-volatile memory device having a vertical structure includes a semiconductor layer, a sidewall insulation layer extending in a vertical direction on the semiconductor layer, and having one or more protrusion regions, first control gate electrodes arranged in the vertical direction on the semiconductor layer, and respectively contacting one of portions of the sidewall insulation layer where the one or more protrusion regions are not formed and second control gate electrodes arranged in the vertical direction on the semiconductor layer, and respectively contacting one of the one or more protrusion regions.

A nonvolatile memory device having a plurality of unit cells, each of the plurality of unit cells includes a first transistor suitable for having a fixed threshold voltage, and a second transistor suitable for coupling to the first transistor in parallel and having a variable threshold voltage.

A memory device is disclosed. The memory device includes a substrate, including a substrate, including a source region and a drain region; and a gate stack, formed over a surface of the substrate, wherein the gate stack includes: a tunneling layer; a first layer; a second layer; a third layer; and a blocking layer; wherein each of the tunneling layer and the blocking layer has an oxygen proportion higher than the first, the second and the third layers; the first layer has a highest silicon proportion among the first, the second and the third layers; the second layer has a highest oxygen proportion among the first, the second and the third layers; and the first layer has a highest nitrogen proportion among the first, the second and the third layers. An associated gate stack and a manufacturing method are also disclosed.

A height of an upper surface of a control gate electrode is lower than a highest position of a lower surface of a silicide layer on a memory gate electrode adjacent to the control gate electrode via an ONO film. As a result, a structure in contact with the ONO film between the control gate electrode and the memory gate electrode is only the control gate electrode and the memory gate electrode made of polysilicon.

Some embodiments include a memory cell having charge-trapping-material between a semiconductor channel material and a gating region. The charge-trapping-material includes silicon, nitrogen and trap-enhancing-additive. The trap-enhancing-additive includes one or more of carbon, phosphorus, boron and metal. Some embodiments include an integrated assembly having a stack of alternating first and second levels. The first levels include conductive structures and the second levels are insulative. Channel-material-pillars extend through the stack. Charge-trapping-regions are along the channel-material-pillars and are between the channel-material-pillars and the conductive structures. The charge-trapping-regions include a charge-trapping-material which contains silicon, nitrogen and trap-enhancing-additive. The trap-enhancing-additive includes one or more of carbon, phosphorus, boron and metal.

A method of forming an electronic device comprising forming an initial dielectric material comprising silicon-hydrogen bonds. A deuterium source gas and an oxygen source gas are reacted to produce deuterium species, and the initial dielectric material is exposed to the deuterium species. Deuterium of the deuterium species is incorporated into the initial dielectric material to form a deuterium-containing dielectric material. Additional methods are also disclosed, as are electronic devices and systems comprising the deuterium-containing dielectric material.

A three-dimensional nonvolatile memory device and a method for fabricating the same include a semiconductor substrate, a plurality of active pillars, a plurality of gate electrodes, and a plurality of supporters. The semiconductor substrate includes a memory cell region and a contact region. The active pillars extend in the memory cell region perpendicularly to the semiconductor substrate. The gate electrodes intersect the active pillars, extend from the memory cell region to the contact region and are stacked on the semiconductor substrate. The supporters extend in the contact region perpendicularly to the semiconductor substrate to penetrate at least one or more of the gate electrodes.