Abstract: In a method of fabricating a CMOS transistor, and a CMOS transistor fabricated according to the method, the characteristics of first and second conductivity type MOS transistors are both simultaneously improved. At the same time, the fabrication process is simplified by reducing the number of masks required. The method includes amorphizing the active region of only the second conductivity type MOS transistor, and performing selective etching to form a first recessed region of a first depth in the active region of the first conductivity type MOS transistor and a second recessed region of a second depth that is greater than the first depth in the active region of the second conductivity type MOS transistor.

Abstract: A semiconductor device includes a gate insulator and a gate electrode stacked on a substrate, a source/drain pattern which fills a recess region formed at opposite sides adjacent to the gate electrode, the source/drain pattern being made of silicon-germanium doped with dopants and a metal germanosilicide layer disposed on the source/drain pattern. The metal germanosilicide layer is electrically connected to the source/drain pattern. Moreover, a proportion of germanium amount to the sum of the germanium amount and silicon amount in the metal germanosilicide layer is lower than that of germanium amount to the sum of the germanium amount and silicon amount in the source/drain pattern.

Abstract: A semiconductor device having a field effect transistor according to example embodiments may include a first semiconductor pattern disposed to fill a first recess region and a second semiconductor pattern disposed to fill a second recess region. The first recess region may be shallower than the second recess region and may be disposed adjacent to a channel region. Thus, sufficient stress may be supplied to the channel region to increase the mobility of holes or carriers in a channel and enhance a punchthrough characteristic.

Abstract: A semiconductor device may include a gate pattern formed on a semiconductor substrate. At least one impurity region may be formed in the semiconductor substrate such that at least a portion of the at least one impurity region is disposed under the gate pattern. An epitaxial growth layer may be formed on the at least one impurity region. The epitaxial growth layer may include a first epitaxial growth portion spaced apart from the gate pattern and a second epitaxial growth portion extending toward the gate pattern from the first epitaxial growth portion.

Abstract: A semiconductor device with improved transistor operating and flicker noise characteristics includes a substrate, an analog NMOS transistor and a compressively-strained-channel analog PMOS transistor disposed on the substrate. The device also includes a first etch stop liner (ESL) and a second ESL which respectively cover the NMOS transistor and the PMOS transistor. The relative measurement of flicker noise power of the NMOS and PMOS transistors to flicker noise power of reference unstrained-channel analog NMOS and PMOS transistors at a frequency of 500 Hz is less than 1.

Abstract: A semiconductor device including an impurity doped region and a method of forming the same. The method includes implanting cluster-shaped dopant ions into a semiconductor substrate to form an impurity implantation region. An annealing process is performed on the impurity implantation region to form an impurity doped region.

Abstract: According to some embodiments of the invention, there is provided line photo masks that includes transistors having reinforcement layer patterns and methods of forming the same. The transistors and the methods provide a way of compensating a partially removed amount of a strained silicon layer during semiconductor fabrication processes. To the end, at least one gate pattern is disposed on an active region of a semiconductor substrate. Reinforcement layer patterns are formed to extend respectively from sidewalls of the gate pattern and disposed on a main surface of the semiconductor substrate. Each reinforcement layer pattern partially exposes each sidewall of the gate pattern. Impurity regions are disposed in the reinforcement layer patterns and the active region of the semiconductor substrate and overlap the gate pattern. Spacer patterns are disposed on the reinforcement layer patterns and partially cover the sidewalls of the gate pattern.

Abstract: A semiconductor device and a method of manufacturing the same, including obtaining a semiconductor substrate, forming a device isolating layer having a depression part and a protrusion part in the semiconductor substrate, forming a gate insulating layer and a gate electrode on the semiconductor substrate, forming a spacer in communication with the gate electrode, removing a portion of the semiconductor substrate to form at least one substrate recess region in an upper surface of the semiconductor substrate and at least one substrate remaining portion extending to a same height as the semiconductor substrate, so that the substrate remaining portion forms a sidewall of the substrate recess region and is in communication with the device isolating layer, and forming a substrate epitaxial layer in the substrate recess region.

Abstract: A MOS transistor having a T-shaped gate electrode and a method for fabricating the same are provided, wherein the MOS transistor includes a T-shaped gate electrode on a semiconductor substrate; an L-shaped lower spacer disposed at both sides of the gate electrode to cover a top surface of the semiconductor substrate; and low-, mid-, and high-concentration impurity regions formed in the semiconductor substrate of both sides of the gate electrode. The high-concentration impurity region is disposed in the semiconductor substrate next to the lower spacer and the mid-concentration impurity region is disposed between the high- and low-concentration impurity regions. A MOS transistor according to the present invention provides a decrease in a capacitance, a decrease in a channel length, and an increase in a cross-sectional area of the gate electrode. At the same time, the mid-concentration impurity region provides a decrease in a source/drain resistance Rsd.

Abstract: A method of forming a silicon-on-insulator (SOI) semiconductor substrate includes implanting hydrogen ions into a support substrate to form a microbubble layer apart from a surface of the support substrate, forming an SOI layer on the microbubble layer, forming a diffusion barrier layer over the SOI layer, forming a buried oxide layer on a handle substrate, contacting the diffusion barrier layer with the buried oxide layer to be bonded, and annealing the bonded support and handle substrates to separate the support substrate from the SOI layer, wherein the diffusion barrier layer is formed by an insulating layer having a lower impurity diffusion coefficient as compared with the buried oxide layer.

Abstract: CMOS integrated circuit devices include an electrically insulating layer and an unstrained silicon active layer on the electrically insulating layer. An insulated gate electrode is also provided on a surface of the unstrained silicon active layer. A Si1-xGex layer is also disposed between the electrically insulating layer and the unstrained silicon active layer. The Si1-xGex layer forms a first junction with the unstrained silicon active layer and has a graded concentration of Ge therein that decreases monotonically in a first direction extending from a peak level towards the surface of the unstrained silicon active layer. The peak Ge concentration level is greater than x=0.15 and the concentration of Ge in the Si1-xGex layer varies from the peak level to a level less than about x=0.1 at the first junction. The concentration of Ge at the first junction may be abrupt. More preferably, the concentration of Ge in the Si1-xGex layer varies from the peak level where 0.2<x<0.

Abstract: A silicon-on-insulator (SOI) semiconductor substrate includes a semiconductor substrate, a buried oxide layer formed on the semiconductor substrates an SOI layer formed on the buried oxide layer, and a diffusion barrier layer interposed between the buried oxide layer and the SOI layer, wherein the diffusion barrier layer is an insulating layer having a lower impurity diffusion coefficient as compared with the buried oxide layer.

Abstract: CMOS integrated circuit devices include an electrically insulating layer and an unstrained silicon active layer on the electrically insulating layer. An insulated gate electrode is also provided on a surface of the unstrained silicon active layer. A Si1-xGex layer is also disposed between the electrically insulating layer and the unstrained silicon active layer. The Si1-xGex layer forms a first junction with the unstrained silicon active layer and has a graded concentration of Ge therein that decreases monotonically in a first direction extending from a peak level towards the surface of the unstrained silicon active layer. The peak Ge concentration level is greater than x=0.15 and the concentration of Ge in the Si1-xGex layer varies from the peak level to a level less than about x=0.1 at the first junction. The concentration of Ge at the first junction may be abrupt. More preferably, the concentration of Ge in the Si1-xGex layer varies from the peak level where 0.2<x<0.

Abstract: A semiconductor device includes a substrate having a semiconductor channel region therein. A gate electrode is provided on the channel region. A SiGeC stress-inducing region is provided adjacent the channel region. The SiGeC region is configured to form a semiconductor junction with the channel region and induce a net mobility-enhancing stress in a portion of the channel region. The SiGeC region may have a Ge/C atomic ratio of less than about 12. The SiGeC region also has a sufficient concentration of substitutional C atoms therein to induce a net tensile stress in the portion of the channel region, which has a different lattice constant relative to the SiGeC region.

Abstract: Example embodiments relate to a method of manufacturing a semiconductor device. Other example embodiments relate to a method of manufacturing a metal-oxide-semiconductor (MOS) transistor having an epitaxial region disposed in a lower portion of sidewalls of a gate pattern. Provided is a method of manufacturing a MOS transistor having an epitaxial region which improves an epitaxial growth rate and which may have fewer defects.

Abstract: A method of forming an SOI semiconductor substrate and the SOI semiconductor substrate formed thereby, is provided. The method includes forming sequentially buried oxide, diffusion barrier and SOI layers on a semiconductor substrate. The diffusion barrier layer is formed by an insulating layer having a lower impurity diffusion coefficient as compared with the buried oxide layer. The diffusion barrier layer serves to prevent impurities implanted into the SOI layer from being diffused into the buried oxide layer or the semiconductor substrate.

Abstract: A semiconductor device and method of manufacturing the semiconductor device are provided. The semiconductor device may include a semiconductor substrate, a gate insulation layer and a gate electrode, a first spacer, a second spacer, an epitaxial pattern, and/or source/drain regions. The gate insulation layer and the gate electrode may be formed on the semiconductor substrate. The first spacer may be formed on sidewalls of the gate electrode. The second spacer may be formed on sidewalls of the first spacer. The epitaxial pattern may be formed between the second spacer and the semiconductor substrate such that an outside profile of the epitaxial pattern is aligned with an outside profile of the second spacer. The source/drain regions may include primary source/drain regions that are aligned with the first spacer. The primary source/drain regions may be formed in the epitaxial pattern and the semiconductor substrate.

Abstract: Low defect epitaxial semiconductor substrates having a gettering function and methods of fabricating such substrates are described. A substrate in accordance with this invention includes a semiconductor substrate, a non-carrier characteristic dopant layer formed in the semiconductor substrate, a carrier characteristic dopant layer including the non-carrier characteristic dopant layer therein, and an epi-layer formed on a surface of the semiconductor substrate.

Abstract: There is provided a method of fabricating a MOS transistor using a total gate silicidation process. The method includes forming an insulated gate pattern on a semiconductor substrate. The insulated gate pattern includes a silicon pattern and a sacrificial layer pattern, which are sequentially stacked. Spacers covering sidewalls of the gate pattern are formed, and source/drain regions are formed by injecting impurity ions into the semiconductor substrate using the spacers and the gate pattern as ion injection masks. The silicon pattern is exposed by removing the sacrificial layer pattern on the semiconductor substrate having the source/drain regions. The exposed silicon pattern is fully converted into a gate silicide layer, and concurrently a source/drain silicide layer is selectively formed on the surface of the source/drain regions.

Abstract: In an example embodiment of the method of manufacturing an epitaxial semiconductor substrate, a gettering layer is grown over a semiconductor substrate. An epitaxial layer may then be formed over the gettering layer, and a semiconductor device may be formed on the epitaxial layer.