A silicon carbide semiconductor device includes a silicon carbide substrate, a gate insulating film, a gate electrode, an interlayer insulating film, and a gate interconnection. The silicon carbide substrate includes: a first impurity region; a second impurity region provided on the first impurity region; and a third impurity region provided on the second impurity region so as to be separated from the first impurity region. A trench has a side portion and a bottom portion, the side portion extending to the first impurity region through the third impurity region and the second impurity region, the bottom portion being located in the first impurity region. When viewed in a cross section, the interlayer insulating film extends from above the third impurity region to above the gate electrode so as to cover the corner portion.

One method disclosed herein includes, among other things, forming a line-end protection layer in an opening on an entirety of each opposing, spaced-apart first and second end face surfaces of first and second spaced-apart gate electrode structures, respectively, and forming a sidewall spacer adjacent opposing sidewall surfaces of each of the gate electrode structures but not adjacent the opposing first and second end face surfaces having the line-end protection layer positioned thereon.

A method for forming a 3D NAND structure includes providing a semiconductor substrate; forming a control gate structure having a plurality of staircase-stacked layers, each layer has a first end and a second end; forming a dielectric layer covering the semiconductor substrate, and the control gate structure; forming a hard mask layer on the dielectric layer; patterning the hard mask layer to form a plurality of openings above corresponding second ends of the layers of the control gate structure; forming a photoresist layer on the hard mask layer; repeating a photoresist trimming process and a first etching process to sequentially expose the openings, and to form a plurality of holes with predetermined depths in the dielectric layer; performing a second etching process to etch the plurality of holes until surfaces of the second ends are exposed to form through holes; and forming metal vias in the through holes.

A method for forming a steeped oxide on a substrate is described: successively forming a first pad oxide layer, a nitride layer, a second pad oxide layer and a poly layer on the substrate; etching the poly layer to have an opening for the stepped oxide region; isotropically etching the second pad oxide layer to the nitride layer through the opening to form a stepped trench; isotropically etching the nitride layer to the first pad oxide layer through the opening to expand the stepped trench; filling the stepped trench with dielectric material to form a dielectric layer; planarizing the dielectric layer; removing the poly layer; removing the second pad oxide layer; removing the nitride layer; removing the portion of the first pad oxide layer uncovered by the dielectric layer such that the remaining first pad oxide layer together the remaining dielectric layer forms the stepped oxide.

Integrated circuits are disclosed in which the strain properties of adjacent pFETs and nFETs are independently adjustable. The pFETs include compressive-strained SiGe on a silicon substrate, while the nFETs include tensile-strained silicon on a strain-relaxed SiGe substrate. Adjacent n-type and p-type FinFETs are separated by electrically insulating regions formed by a damascene process. During formation of the insulating regions, the SiGe substrate supporting the n-type devices is permitted to relax elastically, thereby limiting defect formation in the crystal lattice of the SiGe substrate.

Protective dielectrics are discussed generally herein. In one or more embodiments, a three-dimensional vertical memory may include a protective dielectric material. A device may include an etch stop material, a first control gate (CG) over the etch stop material, a first CG recess adjacent the first CG, a trench adjacent the first CG recess, and an at least partially oxidized polysilicon on at least a portion of the etch stop material. The at least partially oxidized polysilicon may line a sidewall of the trench and may line the first CG recess.

An electrical device comprising a base semiconductor layer of a silicon including material; a dielectric layer present on the base semiconductor layer; a first III-V semiconductor material area present in a trench in the dielectric layer, wherein a via of the III-V semiconductor material extends from the trench through the dielectric layer into contact with the base semiconductor layer; a second III-V semiconductor material area present in the trench in the dielectric layer wherein the second III-V semiconductor material area does not have a via extending through the dielectric layer into contact with the base semiconductor layer; and a semiconductor device present on the second III-V semiconductor material area, wherein the first III-V semiconductor material area and the second III-V semiconductor material area are separated by a low aspect ratio trench extending to the dielectric layer.

The present invention relates generally to semiconductors, and more particularly, to a structure and method of minimizing shorting between epitaxial regions in small pitch fin field effect transistors (FinFETs). In an embodiment, a dielectric region may be formed in a middle portion of a gate structure. The gate structure be formed using a gate replacement process, and may cover a middle portion of a first fin group, a middle portion of a second fin group and an intermediate region of the substrate between the first fin group and the second fin group. The dielectric region may be surrounded by the gate structure in the intermediate region. The gate structure and the dielectric region may physically separate epitaxial regions formed on the first fin group and the second fin group from one another.

A semiconductor device and a method for manufacturing the same are disclosed, which include a gate electrode material in a recess or a buried gate cell structure, a polysilicon material doped with impurities over a sidewall of a recess located over the gate electrode material, and a junction formed by an annealing or a rapid thermal annealing (RTA) process, thereby establishing a degree overlap between a gate electrode material of a buried gate and a junction.

A flash memory cell structure includes a semiconductor substrate, a pad dielectric layer, a floating gate, a control gate, and a blocking layer. The pad dielectric layer is disposed on the semiconductor substrate. The floating gate is disposed over the pad dielectric layer, in which the floating gate has a top surface opposite to the pad dielectric layer, and the top surface includes at least one recess formed thereon. The control gate is disposed over the top surface of the floating gate. The blocking layer is disposed between the floating gate and the control gate.