Methods of forming multi-tiered semiconductor devices are described, along with apparatus and systems that include them. In one such method, an opening is formed in a tier of semiconductor material and a tier of dielectric. A portion of the tier of semiconductor material exposed by the opening is processed so that the portion is doped differently than the remaining semiconductor material in the tier. At least substantially all of the remaining semiconductor material of the tier is removed, leaving the differently doped portion of the tier of semiconductor material as a charge storage structure. A tunneling dielectric is formed on a first surface of the charge storage structure and an intergate dielectric is formed on a second surface of the charge storage structure. Additional embodiments are also described.

A semiconductor device is provided as follows. A tunnel insulation layer is disposed on a substrate. The tunnel insulation layer includes a first silicon oxide layer, a second silicon oxide layer, and a silicon layer interposed between the first silicon oxide layer and the second silicon oxide layer. The silicon layer has a thickness smaller than a thickness of each of the first silicon oxide layer and the second silicon oxide layer. A gate pattern is disposed on the tunnel insulation layer.

An integrated circuit (IC) using high- metal gate (HKMG) technology with an embedded metal-oxide-nitride-oxide-silicon (MONOS) memory cell is provided. A logic device is arranged on a semiconductor substrate and comprises a logic gate. A memory cell is arranged on the semiconductor substrate and comprises a control transistor and a select transistor laterally adjacent to one another. The control and select transistors respectively comprise a control gate and a select gate, and the control transistor further comprises a charge trapping layer underlying the control gate. The logic gate and one or both of the control and select gates are metal and arranged within respective high dielectric layers. A high--last method for manufacturing the IC is also provided.

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.

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.

The present disclosure provides, in accordance with some illustrative embodiments, a semiconductor device structure including a hybrid substrate comprising an SOI region and a bulk region, the SOI region comprising an active semiconductor layer, a substrate material, and a buried insulating material interposed between the active semiconductor layer and the substrate material, and the bulk region being provided by the substrate material, an insulating structure formed in the hybrid substrate, the insulating structure separating the bulk region and the SOI region, and a gate electrode formed in the bulk region, wherein the insulating structure is in contact with two opposing sidewalls of the gate electrode.

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 lower insulation layer, a plurality of base layer patterns separated from each other on the lower insulation layer, a separation layer pattern between the base layer patterns, a plurality of channels extending in a vertical direction with respect to top surfaces of the base layer patterns, and a plurality of gate lines surrounding outer sidewalls of the channels, being stacked in the vertical direction and spaced apart from each other.

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.