Abstract: In an SOI diode structure, the conventional transistor-like MOS configuration is eliminated by replacing the polysilicon line by a completely dielectric region. This region may be used as an implantation mask to control a dopant gradient of a PN-junction that forms below the dielectric region. Moreover, during the salicide process, the dielectric region prevents the PN-junction from being shorted. Thus, a depletion of the active region caused by the MOS structure may be avoided. Therefore, the functioning of the PN-junction is maintained even for extremely thin semiconductor layers.

Abstract: High-k dielectric spacer elements on the gate electrode of a field effects transistor in combination with an extension region that is formed by dopant diffusion from the high-k spacer elements into the underlying semiconductor region provides for an increased charge carrier density in the extension region. In this way, the limitation of the charge carrier density to approximately the solid solubility of dopants in the extension region may be overcome, thereby allowing extremely shallow extension regions without unduly compromising the transistor performance.

Abstract: An epitaxially grown channel layer is provided on a well structure after ion implantation steps and heat treatment steps are performed to establish a required dopant profile in the well structure. The channel layer may be undoped or slightly doped, as required, so that the finally obtained dopant concentration in the channel layer is significantly reduced compared to a conventional device to thereby provide a retrograde dopant profile in a channel region of a field effect transistor. Additionally, a barrier diffusion layer may be provided between the well structure and the channel layer to reduce up-diffusion during any heat treatments carried out after the formation of the channel layer. The final dopant profile in the channel region may be adjusted by the thickness of the channel layer, the thickness and the composition of the diffusion barrier layer and any additional implantation steps to introduce dopant atoms in the channel layer.

Abstract: An SOI transistor element and a method of fabricating the same is disclosed, wherein a high concentration of stationary point defects is created by including a region within the active transistor area that has a slight lattice mismatch. In one particular embodiment, a silicon germanium layer is provided in the active area having a high concentration of point defects due to relaxing the strain of the silicon germanium layer upon heat treating the transistor element. Due to the point defects, the recombination rate is significantly increased, thereby reducing the number of charged carriers stored in the active area.

Abstract: According to one illustrative embodiment of the present invention, a method of forming a field effect transistor includes the formation of a doped high-k dielectric layer above a substrate including a gate electrode formed over an active region and separated therefrom by a gate insulation layer. A heat treatment is carried out with the substrate to diffuse dopants from the high-k dielectric layer into the active region to form extension regions. The high-k dielectric layer is patterned to form sidewall spacers at sidewalls of the gate electrode and an implantation process is carried out with the sidewall spacers as implantation mask to form source and drain regions.

Abstract: An implanting process for amorphizing a crystalline substrate is proposed according to the present invention. In particular, according to the present invention, amorphous regions are formed in a substrate by exposing the substrate to an ion beam which is kept at a tilt angle between 10 and 80 degrees with respect to the surface of the substrate. Accordingly, ion channeling during subsequent implanting processes is prevented not only in the vertical direction but also in the horizontal direction so that doped regions exhibiting optimum doping profile tailoring may be realized.

Abstract: The introduction of a barrier diffusion material, such as nitrogen, into a silicon-containing conductive region, for example the drain and source regions and the gate electrode of a field effect transistor, allows the formation of nickel silicide, which is substantially thermally stable up to temperatures of 500° C. Thus, the device performance may significantly improve as the sheet resistance of nickel silicide is significantly less than that of nickel disilicide.

Abstract: The present invention provides a technique for forming a metal silicide, such as a cobalt disilicide, even at extremely scaled device dimensions without unduly degrading the film integrity of the metal silicide. To this end, an ion implantation may be performed, advantageously with silicon, prior to a final anneal cycle, thereby correspondingly modifying the grain structure of the precursor of the metal silicide.

Abstract: A cost-efficient and reliable method for assessing lateral dopant profiles includes the estimation of a reference profile formed below a gate structure of a transistor device. The overlap capacitance is then determined for at least two different overlaps, created by different spacer widths, and the lateral extension of a dopant profile to be measured, is estimated on the basis of a relationship between overlap capacitance and spacer width for the reference dopant profile.

Abstract: The polysilicon gate electrode of a MOS transistor may be substantially completely converted into a metal silicide without sacrificing the drain and source junctions in that a thickness of the polysilicon layer, for forming the gate electrode, is targeted to be substantially converted into metal silicide in a subsequent silicidation process. The gate electrode, substantially comprised of metal silicide, offers high conductivity even at critical dimensions in the deep sub-micron range, while at the same time the effect of polysilicon gate depletion is significantly reduced. Manufacturing of the MOS transistor, having the substantially fully-converted metal silicide gate electrode, is essentially compatible with standard MOS process technology.

Abstract: An SOI transistor element and a method of fabricating the same is disclosed, wherein a high concentration of stationary point defects is created by including a region within the active transistor area that has a slight lattice mismatch. In one particular embodiment, a silicon germanium layer is provided in the active area having a high concentration of point defects due to relaxing the strain of the silicon germanium layer upon heat treating the transistor element. Due to the point defects, the recombination rate is significantly increased, thereby reducing the number of charged carriers stored in the active area.

Abstract: The present invention allows the manufacturing of field effect transistors with reduced thermal budget. A first amorphized region and a second amorphized region are formed in a substrate adjacent to the gate electrode by implanting ions of a non-doping element, the presence of which does not significantly alter the conductive properties of the substrate. The formation of the amorphized regions may be performed before or after the formation of a source region, a drain region, an extended source region and an extended drain region. The substrate is annealed to achieve solid phase epitaxial regrowth of the amorphized regions and to activate dopants in the source region, the drain region, the extended source region and the extended drain region.

Abstract: In an SOI diode structure, the conventional transistor-like MOS configuration is eliminated by replacing the polysilicon line by a completely dielectric region. This region may be used as an implantation mask to control a dopant gradient of a PN-junction that forms below the dielectric region. Moreover, during the salicide process, the dielectric region prevents the PN-junction from being shorted. Thus, a depletion of the active region caused by the MOS structure may be avoided. Therefore, the functioning of the PN-junction is maintained even for extremely thin semiconductor layers.

Abstract: A transistor formed on a substrate comprises a gate electrode having a lateral extension at the foot of the gate electrode that is less than the average lateral extension of the gate electrode. The increased cross-section of the gate electrode compared to the rectangular cross-sectional shape of a prior art device provides for a significantly reduced gate resistance while the effective gate length, i.e., the lateral extension of the gate electrode at its foot, may be scaled down to a size of 100 nm and beyond. Moreover, a method for forming the field effect transistor described above is disclosed.

Abstract: A cost-efficient and reliable method for assessing lateral dopant profiles includes the estimation of a reference profile formed below a gate structure of a transistor device. The overlap capacitance is then determined for at least two different overlaps, created by different spacer widths, and the lateral extension of a dopant profile to be measured, is estimated on the basis of a relationship between overlap capacitance and spacer width for the reference dopant profile.

Abstract: A semiconductor device comprises an isolation trench and a contact trench that may contact a buried conductive region. The contact trench comprises insulating sidewall spacers that are formed during the filling of the isolation trench with an insulating material and the subsequent anisotropic etching of the excess material. Thereafter, the contact trench is filled with a conductive material. Thus, the formation of a contact for a buried region may be carried out simultaneously with the formation of a trench isolation structure, thereby minimizing the number of process steps required.

Abstract: The cross-sectional area of polysilicon lines is increased by selectively epitaxially growing an upper portion of the polysilicon line in the presence of a dielectric layer exposing the upper portion. Thus, a substantially T-shaped line is obtained, allowing a minimum bottom-CD while insuring a sufficient high conductivity.

Abstract: An implanting process for amorphizing a crystalline substrate is proposed according to the present invention. In particular, according to the present invention, amorphous regions are formed in a substrate by exposing the substrate to an ion beam which is kept at a tilt angle between 10 and 80 degrees with respect to the surface of the substrate. Accordingly, ion channeling during subsequent implanting processes is prevented not only in the vertical direction but also in the horizontal direction so that doped regions exhibiting optimum doping profile tailoring may be realized.

Abstract: A method for improving the etch behavior of disposable features in the fabrication of a semiconductor device is disclosed. The semiconductor device comprises a bottom anti-reflective coating layer and/or a disposable sidewall spacer which are to be removed in a subsequent etch removal process. The bottom anti-reflective coating layer and/or the disposable sidewall spacer are irradiated by heavy inert ions to alter the structure of the irradiated features and to increase concurrently the etch rate of the employed materials, for example, silicon nitride or silicon reacted nitride.

Abstract: The present invention allows the manufacturing of field effect transistors with reduced thermal budget. A first amorphized region and a second amorphized region are formed in a substrate adjacent to the gate electrode by implanting ions of a non-doping element, the presence of which does not significantly alter the conductive properties of the substrate. The formation of the amorphized regions may be performed before or after the formation of a source region, a drain region, an extended source region and an extended drain region. The substrate is annealed to achieve solid phase epitaxial regrowth of the amorphized regions and to activate dopants in the source region, the drain region, the extended source region and the extended drain region.