Abstract: A semiconductor device having a field effect transistor and a method of fabricating the same. In-situ doped epitaxial patterns are respectively formed at both sidewalls of a protruded channel pattern from a substrate by performing an in-situ doped epitaxial growth process. The in-situ doped epitaxial pattern has a conformal impurity concentration throughout. Accordingly, source/drain regions with a conformal impurity concentration are connected throughout a channel width of a channel region including both sidewalls of a protruded channel pattern. As a result, it is possible to maximize a driving current of the filed effect transistor, and an on-off characteristic can be highly stabilized.

Abstract: A trench structure of a semiconductor device includes first and second regions of a substrate having first and second trenches, respectively, the first trench having an aspect ratio larger than that of the second trench, a first insulation material on a bottom and sidewalls of the first trench forming a first sub-trench in the first trench, a second insulation material completely filling the first sub-trench, a third insulation material formed on a bottom and sidewalls of the second trench forming a second sub-trench in the second trench, a fourth insulation material formed on a bottom and sidewalls of the second sub-trench, and a fifth insulation material completely filling a third sub-trench formed in the second sub-trench by the fourth insulation material.

Abstract: In a method of manufacturing a semiconductor device, a preliminary active pattern including gate layers and channel layers is formed on a substrate. The gate layers and the channel layers are alternatively stacked. A hard mask is formed on the preliminary active pattern. The preliminary active pattern is partially etched using the hard mask as an etching mask to expose a surface of the substrate. The etched preliminary active pattern is trimmed to form an active channel pattern having a width less than a lower width of the hard mask. Source/drain layers are formed on exposed side faces of the active channel pattern and the surface. The gate layers are selectively etched to form tunnels. A gate encloses the active channel pattern and filling the tunnels. Related intermediate structures are also disclosed.

Abstract: In a method for forming a gate electrode having an excellent sidewall profile, after a gate structure is formed on a substrate, a first oxide film is formed on a sidewall of the gate structure and on the substrate by re-oxidizing the gate structure and the substrate under an atmosphere including an oxygen gas and an inert gas. The gate structure has a gate oxide film pattern, a polysilicon film pattern and a metal silicide film pattern. A portion of the first oxide film formed on a sidewall of the polysilicon film pattern has a thickness substantially identical to that of a portion of the first oxide film formed on a sidewall of the metal silicide film pattern. A failure of a semiconductor device having the gate electrode can be minimized because the gate electrode has an improved sidewall profile.

Abstract: Methods of forming multi fin Field Effect Transistors (FET) can include forming a first fin having opposing sidewalls protruding from a substrate and epitaxially growing second fins on the opposing sidewalls, where the second fins have respective exposed sidewalls protruding from the substrate. The second fins or the first fin can be removed to provide at least one fin for a multi fin FET.

Abstract: A field effect transistor on an active region of a semiconductor substrate includes a vertically protruding thin-body portion of the semiconductor substrate and a vertically oriented gate electrode at least partially inside a cavity defined by opposing sidewalls of the vertically protruding portion of the substrate. The transistor further includes an insulating layer surrounding an upper portion of the vertically oriented gate electrode and a laterally oriented gate electrode on the insulating layer and connected to a top portion of the vertically oriented gate electrode. Accordingly, a T-shaped gate electrode is defined having a lateral portion on a top surface of a semiconductor substrate and having a vertical portion at least partially inside a cavity defined by opposing sidewalls of a vertically protruding portion of the substrate.

Abstract: Unit cells of metal oxide semiconductor (MOS) transistors are provided including an integrated circuit substrate and a MOS transistor on the integrated circuit substrate. The MOS transistor has a source region, a drain region and a gate region, the gate region being between the source region and the drain region. First and second channel regions are provided between the source and drain regions. The channel region is defined by first and second spaced apart protrusions in the integrated circuit substrate separated by a trench region. The first and second protrusions extend away from the integrated circuit substrate and upper surfaces of the first and second protrusions are substantially planar with upper surfaces of the source and drain regions. A gate electrode is provided in the trench region extending on sidewalls of the first and second spaced apart protrusions and on at least a portion of surfaces of the first and second spaced apart protrusions.

Abstract: An integrated circuit device structure can be formed by forming an implant mask having a window therein on a structure including upper and lower Si layers and an intermediate SiGex layer therebetween. Ions are implanted through the upper Si layer and into a portion of the intermediate SiGex layer exposed through the window in the implant mask and blocking implantation of ions into portions of the intermediate SiGex layer outside the window. The portions of the intermediate SiGex layer outside the window are etched and the portion of the intermediate SiGex layer exposed through the window having ions implanted therein is not substantially etched to form a patterned intermediate SiGex layer.

Abstract: A unit cell of a metal oxide semiconductor (MOS) transistor is provided including an integrated circuit substrate and a MOS transistor on the integrated circuit substrate. The MOS transistor has a source region, a drain region and a gate. The gate is between the source region and the drain region. First and second spaced apart buffer regions are provided beneath the source region and the drain region and between respective ones of the source region and integrated circuit substrate and the drain region and the integrated circuit substrate.

Abstract: In a method for forming a gate electrode having an excellent sidewall profile, after a gate structure is formed on a substrate, a first oxide film is formed on a sidewall of the gate structure and on the substrate by re-oxidizing the gate structure and the substrate under an atmosphere including an oxygen gas and an inert gas. The gate structure has a gate oxide film pattern, a polysilicon film pattern and a metal silicide film pattern. A portion of the first oxide film formed on a sidewall of the polysilicon film pattern has a thickness substantially identical to that of a portion of the first oxide film formed on a sidewall of the metal silicide film pattern. A failure of a semiconductor device having the gate electrode can be minimized because the gate electrode has an improved sidewall profile.

Abstract: A trench structure and method for semiconductor device isolation are disclosed, including first and second regions of a substrate having first and second trenches, respectively, the first trench having an aspect ratio larger than that of the second trench, a first insulation material on a bottom and sidewalls of the first trench forming a first sub-trench in the first trench, a second insulation material completely filling the first sub-trench, a third insulation material formed on a bottom and sidewalls of the second trench forming a second sub-trench in the second trench, a fourth insulation material formed on a bottom and sidewalls of the second sub-trench, and a fifth insulation material completely filling a third sub-trench formed in the second sub-trench by the fourth insulation material. Trench structures may be formed in high and low aspect ratio trenches in a substrate without the generation of voids therein.