Abstract: The semiconductor device includes a first multi-channel active pattern protruding from a substrate, and having a first height, a second multi-channel active pattern on the substrate, being spaced apart from the substrate, and having a second height that is less than the first height, and a gate electrode on the substrate, intersecting the first multi-channel active pattern and the second multi-channel active pattern.

Abstract: A semiconductor device includes a substrate including a first region and a second region, fin type active areas extending in a first direction away from the substrate in each of the first and second regions, a plurality of nanosheets extending parallel to an upper surface of the fin type active areas and being spaced apart from the upper surface of the fin type active areas, a gate extending over the fin type active areas in a second direction crossing the first direction, a gate dielectric layer interposed between the gate and each of the nanosheets, first source and drain regions included in the first region and second source and drain regions included in the second region, and insulating spacers interposed between the fin type active areas and the nanosheets, wherein air spacers are interposed between the insulating spacers and the first source and drain regions.

Abstract: A method of manufacturing semiconductor device includes forming a plurality of sacrificial layers and a plurality of semiconductor layers repeatedly and alternately stacked on a substrate, partially removing the sacrificial layers, forming spacers in removed regions of the sacrificial layers, and replacing remaining portions of the sacrificial layers with a gate electrode. Each of the sacrificial layers includes first portions disposed adjacent to the plurality of semiconductor layers and a second portions disposed between the first portions. The second portion having a different composition from the first portions.

Abstract: A semiconductor device may include: a semiconductor substrate, a device isolating layer embedded within the semiconductor substrate and defining an active region, a channel region formed in the active region, a gate electrode disposed above the channel region, a gate insulating layer provided between the channel region and the gate electrode, and a silicon germanium epitaxial layer adjacent to the channel region within the active region and including a first epitaxial layer containing a first concentration of germanium, a second epitaxial layer containing a second concentration of germanium, higher than the first concentration, and a third epitaxial layer containing a third concentration of germanium, lower than the second concentration, the first to third epitaxial layers being sequentially stacked on one another in that order.

Abstract: A semiconductor device includes a drain, a source, a gate electrode, and a nanowire between the source and drain. The nanowire has a first section with a first thickness and a second section with a second thickness greater than the first thickness. The second section is between the first section and at least one of the source or drain. The first nanowire includes a channel when a voltage is applied to the gate electrode.

Abstract: A semiconductor device may include: a semiconductor substrate, a device isolating layer embedded within the semiconductor substrate and defining an active region, a channel region formed in the active region, a gate electrode disposed above the channel region, a gate insulating layer provided between the channel region and the gate electrode, and a silicon germanium epitaxial layer adjacent to the channel region within the active region and including a first epitaxial layer containing a first concentration of germanium, a second epitaxial layer containing a second concentration of germanium, higher than the first concentration, and a third epitaxial layer containing a third concentration of germanium, lower than the second concentration, the first to third epitaxial layers being sequentially stacked on one another in that order.

Abstract: A semiconductor device includes a semiconductor substrate. A first fin extends in a first direction. A first nano sheet structure includes at least two first nano sheets which extend in the first direction parallel to an upper surface of the first fin. A second fin extends in the first direction. A second nano sheet structure includes at least two second nano sheets which extend in the first direction parallel to an upper surface of the second fin. At least one of the at least two first nano sheets has a different thickness from at least one of the at least two second nano sheets.

Abstract: A semiconductor device includes at least a first wire pattern, a gate electrode, a semiconductor pattern, a gate insulating layer, and a first spacer. The first wire pattern is on a substrate and isolated from the substrate. The gate electrode surrounds and intersects the first wire pattern. The semiconductor pattern is on both sides of the first wire pattern, and the semiconductor pattern includes a portion which overlaps the first wire pattern. The gate insulating layer is disposed between the gate electrode and the first wire pattern, and the gate insulating layer surrounds the first wire pattern.

Abstract: A semiconductor device includes an active fin structure extending in a first direction, the active fin structure including protruding portions divided by a recess, a plurality of gate structures extending in a second direction crossing the first direction and covering the protruding portions of the active fin structure, a first epitaxial pattern in a lower portion of the recess between the gate structures, a second epitaxial pattern on a portion of the first epitaxial pattern, the second epitaxial pattern contacting a sidewall of the recess, and a third epitaxial pattern on the first and second epitaxial patterns, the third epitaxial pattern filling the recess.

Abstract: Provided is a method of fabricating a semiconductor device. The method includes forming a gate pattern on a semiconductor substrate, injecting amorphization elements into the semiconductor substrate to form an amorphous portion at a side of the gate pattern, removing the amorphous portion to form a recess region, and forming a source/drain pattern in the recess region. When the recess region is formed, an etch rate of the amorphous portion is substantially the same in two different directions (e.g., <111> and any other direction) of the semiconductor substrate.

Abstract: Provided is a method of manufacturing a semiconductor device including: forming a gate electrode structure on an active region of a semiconductor substrate; forming recesses in regions positioned on both sides of the gate electrode structure on the active region; performing a pre-treatment on the recesses using an inert gas plasma; growing epitaxial layers for a source and a drain on the pre-treated recesses; and forming a source electrode structure and a drain electrode structure in the epitaxial layers for the source and the drain, respectively. Also provided is a method in which, after an etching process for forming recesses and/or after an etching process for forming a contact hole, an etched surface may be treated with an inert gas plasma before growing an epitaxial layer. Thus, one or two types of plasma treatment may be employed in the method.

Abstract: A semiconductor device includes an active fin structure extending in a first direction, the active fin structure including protruding portions divided by a recess, a plurality of gate structures extending in a second direction crossing the first direction and covering the protruding portions of the active fin structure, a first epitaxial pattern in a lower portion of the recess between the gate structures, a second epitaxial pattern on a portion of the first epitaxial pattern, the second epitaxial pattern contacting a sidewall of the recess, and a third epitaxial pattern on the first and second epitaxial patterns, the third epitaxial pattern filling the recess.

Abstract: Provided is a method of fabricating a semiconductor device. The method includes forming a gate pattern on a semiconductor substrate, injecting amorphization elements into the semiconductor substrate to form an amorphous portion at a side of the gate pattern, removing the amorphous portion to form a recess region, and forming a source/drain pattern in the recess region. When the recess region is formed, an etch rate of the amorphous portion is substantially the same in two different directions (e.g., <111> and any other direction) of the semiconductor substrate.

Abstract: A semiconductor device may include: a semiconductor substrate, a device isolating layer embedded within the semiconductor substrate and defining an active region, a channel region formed in the active region, a gate electrode disposed above the channel region, a gate insulating layer provided between the channel region and the gate electrode, and a silicon germanium epitaxial layer adjacent to the channel region within the active region and including a first epitaxial layer containing a first concentration of germanium, a second epitaxial layer containing a second concentration of germanium, higher than the first concentration, and a third epitaxial layer containing a third concentration of germanium, lower than the second concentration, the first to third epitaxial layers being sequentially stacked on one another in that order.

Abstract: Provided is a method of manufacturing a semiconductor device including: forming a gate electrode structure on an active region of a semiconductor substrate; forming recesses in regions positioned on both sides of the gate electrode structure on the active region; performing a pre-treatment on the recesses using an inert gas plasma; growing epitaxial layers for a source and a drain on the pre-treated recesses; and forming a source electrode structure and a drain electrode structure in the epitaxial layers for the source and the drain, respectively. Also provided is a method in which, after an etching process for forming recesses and/or after an etching process for forming a contact hole, an etched surface may be treated with an inert gas plasma before growing an epitaxial layer. Thus, one or two types of plasma treatment may be employed in the method.

Abstract: A method for fabricating a semiconductor device comprises forming a dummy gate pattern and a spacer that is arranged on a sidewall of the dummy gate pattern on a substrate, forming an air gap on both sides of the dummy gate pattern by removing the spacer, exposing the substrate by removing the dummy gate pattern, and sequentially forming a gate insulating film including a high-k insulating film and a metal gate electrode on the exposed substrate.

Abstract: A semiconductor device includes a fin type active pattern protruding above a device isolation layer, a gate electrode on the device isolation layer and intersecting the fin type active pattern, an elevated source/drain on the fin type active pattern at both sides of the gate electrode, and a fin spacer on a side wall of the fin type active pattern, the fin spacer having a low dielectric constant and being between the device isolation layer and the elevated source/drain.

Abstract: A method for fabricating a semiconductor device comprises forming a dummy gate pattern and a spacer that is arranged on a sidewall of the dummy gate pattern on a substrate, forming an air gap on both sides of the dummy gate pattern by removing the spacer, exposing the substrate by removing the dummy gate pattern, and sequentially forming a gate insulating film including a high-k insulating film and a metal gate electrode on the exposed substrate.