A method of manufacturing a semiconductor device, the method including forming a structure on a substrate, the structure including a metal pattern, at least a portion of the metal pattern being exposed; forming a preliminary buffer oxide layer to cover the structure, a metal oxide layer being formed at the exposed portion of the metal pattern; and deoxidizing the metal oxide layer so that the preliminary buffer oxide layer is transformed into a buffer oxide layer.

A semiconductor device is disclosed, including a plurality of gate rings formed on a substrate and concentrically surrounding a first doped region formed in the substrate. The gate rings are equipotentially interconnected by at least a connecting structure. A second doped region is formed in the substrate, exposed from the space between adjacent gate rings. A third doped region is formed in the substrate adjacent to the outer perimeter of the outermost gate ring. The first doped region, the third doped region and the gate rings are electrically biased and the second doped regions are electrically floating.

A method of fabricating features of a vertical transistor include performing a first etch process to form a first portion of a fin in a substrate; depositing a spacer material on sidewalls of the first portion of the fin; performing a second etch process using the spacer material as a pattern to elongate the fin and form a second portion of the fin in the substrate, the second portion having a width that is greater than the first portion; oxidizing a region of the second portion of the fin beneath the spacer material to form an oxidized channel region; and removing the oxidized channel region to form a vacuum channel.

A method is presented for forming a semiconductor device. The method includes forming an oxygen containing interfacial layer on a semiconductor substrate, forming a hafnium oxide layer on the interfacial layer, the hafnium oxide layer crystallizing to a non-centrosymmetric phase in a final structure, forming a first electrode containing a scavenging metal, which reduces a thickness of the interfacial layer via an oxygen scavenging reaction in the final structure, on the hafnium oxide layer, and forming a second electrode on the first electrode.

Some embodiments include methods of forming voids within semiconductor constructions. In some embodiments the voids may be utilized as microstructures for distributing coolant, for guiding electromagnetic radiation, or for separation and/or characterization of materials. Some embodiments include constructions having micro-structures therein which correspond to voids, conduits, insulative structures, semiconductor structures or conductive structures.

This disclosure provides a horizontal structure by using a double STI recess method. The double STI recess method includes: forming a plurality of fins on the substrate; forming shallow trench isolation between the fins; performing first etch-back on the shallow trench isolation; forming source and drain regions adjacent to channels of the fins; and performing second etch-back on the shallow trench isolations to expose a lower portion of the fins as a larger process window for forming gates of the fins.

A semiconductor device capable of high speed operation is provided. Further, a semiconductor device in which change in electric characteristics due to a short channel effect is hardly caused is provided. An oxide semiconductor having crystallinity is used for a semiconductor layer of a transistor. A channel formation region, a source region, and a drain region are formed in the semiconductor layer. The source region and the drain region are formed by self-aligned process in which one or more elements selected from Group 15 elements are added to the semiconductor layer with the use of a gate electrode as a mask. The source region and the drain region can have a wurtzite crystal structure.

A method for fabricating a semiconductor device includes forming a stacked structure on a substrate, forming a first interlayer dielectric covering the stacked structure, and forming a second interlayer dielectric covering the first interlayer dielectric. The stacked structure includes a stepwise shape. The first interlayer dielectric includes at least one step portion having a slope surface connecting a first top surface to a second top surface. The first top surface and the sloped surface define a first angle that is an obtuse angle. A level of the second top surface is higher than a level of the first top surface.

The present invention provides a flash cell structure and a method of fabricating the same. The flash cell structure includes a semiconductor substrate, a stacked gate structure disposed on the semiconductor substrate, a first doped region disposed in the semiconductor substrate at a side of the stacked gate structure, a first dielectric layer, a second dielectric layer, and an erase gate. The stacked gate structure includes a floating gate insulated from the semiconductor substrate and a control gate disposed on the floating gate and insulated from the floating gate. The first dielectric layer is disposed on a sidewall of the floating gate. The second dielectric layer is disposed on the first doped region. A thickness of the first dielectric layer is less than a thickness of the second dielectric layer.

A method of forming a vertical fin field effect transistor (vertical finFET) with a strained channel, including forming one or more vertical fins on a substrate, forming a sacrificial stressor layer adjacent to the one or more vertical fins, wherein the sacrificial stressor layer imparts a strain in the adjacent vertical fins, forming a fin trench through one or more vertical fins and the sacrificial stressor layer to form a plurality of fin segments and a plurality of sacrificial stressor layer blocks, forming an anchor wall adjacent to and in contact with one or more fin segment endwalls, and removing at least one of the plurality of the sacrificial stressor layer blocks, wherein the anchor wall maintains the strain of the adjacent fin segments after removal of the sacrificial stressor layer blocks adjacent to the fin segment with the adjacent anchor wall.