A semiconductor device includes a substrate, a plurality of insulators, a liner structure and a gate stack. The substrate has fins and trenches in between the fins. The insulators are disposed within the trenches of the substrate. The liner structure is disposed on the plurality of insulators and across the fins, wherein the liner structure comprises sidewall portions and a cap portion, the sidewall portions is covering sidewalls of the fins, the cap portion is covering a top surface of the fins and joined with the sidewall portions, and a maximum thickness T.sub.1 of the cap portion is greater than a thickness T.sub.2 of the sidewall portions. The gate stack is disposed on the liner structure and across the fins.

An integrated circuit device includes: a pair of width-setting patterns over a substrate, the pair of width-setting patterns defining a width of a gate structure space in a first direction and extending in a second direction intersecting with the first direction. A gate electrode layer is provided that extends in the gate structure space along the second direction. A gate insulating layer is provided in the gate structure space and between the substrate and the gate electrode layer. An insulating spacer is provides on the pair of width-setting patterns, the insulating spacer covering both sidewalls of the gate electrode layer, wherein the pair of width-setting patterns have a carbon content that is greater than a carbon content of the insulating spacer.

Provided is a semiconductor device in which deterioration of electric characteristics which becomes more noticeable as the semiconductor device is miniaturized can be suppressed. The semiconductor device includes a first oxide film, an oxide semiconductor film over the first oxide film, a source electrode and a drain electrode in contact with the oxide semiconductor film, a second oxide film over the oxide semiconductor film, the source electrode, and the drain electrode, a gate insulating film over the second oxide film, and a gate electrode in contact with the gate insulating film. A top end portion of the oxide semiconductor film is curved when seen in a channel width direction.

Semiconductor devices, fin field effect transistor (FinFET) devices, and methods of manufacturing semiconductor devices are disclosed. In some embodiments, a semiconductor device includes a substrate comprising a first fin and a second fin. A first epitaxial fin is disposed over the first fin, and a second epitaxial fin is disposed over the second fin. The second fin is proximate the first fin. The first epitaxial fin and the second epitaxial fin have an upper portion with a substantially pillar shape.

A semiconductor device can include a substrate and a fin body that protrudes from a surface of the substrate. The fin body can include a lower portion having a first lattice structure and an upper portion, separated from the lower portion by a boundary, the upper portion having a second lattice structure that is different than the first lattice structure. An epitaxially grown epitxial layer can be on the lower and upper portions.

Provided is a semiconductor device and a fabricating method thereof. The semiconductor device includes a first trench having a first depth to define a fin, a second trench formed directly adjacent the first trench having a second depth that is greater than the first depth, a field insulation layer filling a portion of the first trench and a portion of the second trench, and a protrusion structure protruding from a bottom of the first trench and being lower than a surface of the field insulation layer.

The invention provides a method of forming a semiconductor structure, which include: providing an intermediate semiconductor structure having semiconductor substrate, a fin having an EG oxide layer in contact with at least a portion of the fin, and a gate stack disposed over a portion of the fin; forming a silicon nitride layer over portions of the fin that are not located under the gate stack; and after forming the silicon nitride layer, performing one or more ion implantation steps on the intermediate semiconductor structure. The invention also provides a method of forming a semiconductor structure including: providing an intermediate semiconductor structure having a semiconductor substrate, a fin having an EG oxide layer in contact with at least a portion of the fin, and a gate material disposed over the fin; forming, over the fin and gate material of the intermediate semiconductor structure, a gate stack hardmask including an oxide layer; forming a silicon nitride barrier layer on the oxide layer of the gate stack hardmask; performing one or more gate stack hardmask patterning steps; removing the EG oxide layer from portions of the fin that are not located under the gate; and subsequent to removing the EG oxide layer from portions of the fin that are not located under the gate, performing one or more ion implantation steps.

A fin field effect transistor (FinFET), and a method of forming, is provided. The FinFET has a fin having one or more semiconductor layers epitaxially grown on a substrate. A first passivation layer is formed over the fins, and isolation regions are formed between the fins. An upper portion of the fins are reshaped and a second passivation layer is formed over the reshaped portion. Thereafter, a gate structure may be formed over the fins and source/drain regions may be formed.

A conventional DRAM needs to be refreshed at an interval of several tens of milliseconds to hold data, which results in large power consumption. In addition, a transistor therein is frequently turned on and off; thus, deterioration of the transistor is also a problem. These problems become significant as the memory capacity increases and transistor miniaturization advances. A transistor is provided which includes a wide-gap semiconductor and has a trench structure including a trench for a gate electrode and a trench for element isolation. Even when the distance between a source electrode and a drain electrode is decreased, the occurrence of a short-channel effect can be suppressed by setting the depth of the trench for the gate electrode as appropriate.

A method for memory device fabrication includes forming a plurality of continuous fins on a substrate. An insulator material is formed around the fins. The continuous fins are etched into segmented fins to form exposed areas between the segmented fins. An insulator material is formed in the exposed areas wherein the insulator material in the exposed areas is formed higher than the insulator material around the fins. A metal is formed over the fins and the insulator material. The metal formed over the exposed areas is formed to a shallower depth than over the fins.