Abstract: By appropriately orienting the channel length direction with respect to the crystallographic characteristics of the silicon layer, the stress-inducing effects of strained silicon/carbon material may be significantly enhanced compared to conventional techniques. In one illustrative embodiment, the channel may be oriented along the <100> direction for a (100) surface orientation, thereby providing an electron mobility increase of approximately a factor of four.

Abstract: By forming an etch control material with increased thickness on a first stressed dielectric layer in a dual stress liner approach, the surface topography may be smoothed prior to the deposition of the second stressed dielectric material, thereby allowing the deposition of an increased amount of stressed material while not contributing to yield loss caused by deposition-related defects.

Abstract: By appropriately adapting the length direction and width directions of transistor devices with respect to the crystallographic orientation of the semiconductor material such that identical vertical and horizontal growth planes upon re-crystallizing amorphized portions are obtained, the number of corresponding stacking faults may be significantly reduced. Hence, transistor elements with extremely shallow PN junctions may be formed on the basis of pre-amorphization implantation processes while substantially avoiding any undue side effects typically obtained in conventional techniques due to stacking faults.

Abstract: By combining a respectively adapted lattice mismatch between a first semiconductor material in a channel region and an embedded second semiconductor material in an source/drain region of a transistor, the strain transfer into the channel region is increased. According to one embodiment of the invention, the lattice mismatch may be adapted by a biaxial strain in the first semiconductor material. According to one embodiment, the lattice mismatch may be adjusted by a biaxial strain in the first semiconductor material. In particular, the strain transfer of strain sources including the embedded second semiconductor material as well as a strained overlayer is increased. According to one illustrative embodiment, regions of different biaxial strain may be provided for different transistor types.

Abstract: A method of forming a field effect transistor comprises providing a substrate comprising a biaxially strained layer of a semiconductor material. A gate electrode is formed on the biaxially strained layer of semiconductor material. A raised source region and a raised drain region are formed adjacent the gate electrode. Ions of a dopant material are implanted into the raised source region and the raised drain region to form an extended source region and an extended drain region. Moreover, in methods of forming a field effect transistor according to embodiments of the present invention, a gate electrode can be formed in a recess of a layer of semiconductor material. Thus, a field effect transistor wherein a source side channel contact region and a drain side channel contact region located adjacent a channel region are subject to biaxial strain can be obtained.

Abstract: The threshold voltage of a sophisticated transistor may be adjusted by providing a specifically designed semiconductor alloy in the channel region of the transistor, wherein a negative effect of this semiconductor material with respect to inducing a strain component in the channel region may be reduced or over-compensated for by additionally incorporating a strain-adjusting species. For example, a carbon species may be incorporated in the channel region, the threshold voltage of which may be adjusted on the basis of a silicon/germanium alloy of a P-channel transistor. Consequently, sophisticated metal gate electrodes may be formed in an early manufacturing stage.

Abstract: By recessing drain and source regions, a highly stressed layer, such as a contact etch stop layer, may be formed in the recess in order to enhance the strain generation in the adjacent channel region of a field effect transistor. Moreover, a strained semiconductor material may be positioned in close proximity to the channel region by reducing or avoiding undue relaxation effects of metal silicides, thereby also providing enhanced efficiency for the strain generation. In some aspects, both effects may be combined to obtain an even more efficient strain-inducing mechanism.

Abstract: A method of forming a field effect transistor comprises providing a substrate comprising a biaxially strained layer of a semiconductor material. A gate electrode is formed on the biaxially strained layer of semiconductor material. A raised source region and a raised drain region are formed adjacent the gate electrode. Ions of a dopant material are implanted into the raised source region and the raised drain region to form an extended source region and an extended drain region. Moreover, in methods of forming a field effect transistor according to embodiments of the present invention, a gate electrode can be formed in a recess of a layer of semiconductor material. Thus, a field effect transistor wherein a source side channel contact region and a drain side channel contact region located adjacent a channel region are subject to biaxial strain can be obtained.

Abstract: By recessing drain and source regions, a highly stressed layer, such as a contact etch stop layer, may be formed in the recess in order to enhance the strain generation in the adjacent channel region of a field effect transistor. Moreover, a strained semiconductor material may be positioned in close proximity to the channel region by reducing or avoiding undue relaxation effects of metal silicides, thereby also providing enhanced efficiency for the strain generation. In some aspects, both effects may be combined to obtain an even more efficient strain-inducing mechanism.

Abstract: By incorporating carbon by means of ion implantation and a subsequent flash-based or laser-based anneal process, strained silicon/carbon material with tensile strain may be positioned in close proximity to the channel region, thereby enhancing the strain-inducing mechanism. The carbon implantation may be preceded by a pre-amorphization implantation, for instance on the basis of silicon. Moreover, by removing a spacer structure used for forming deep drain and source regions, the degree of lateral offset of the strained silicon/carbon material with respect to the gate electrode may be determined substantially independently from other process requirements. Moreover, an additional sidewall spacer used for forming metal silicide regions may be provided with reduced permittivity, thereby additionally contributing to an overall performance enhancement.

Abstract: A silicon/carbon alloy may be formed in drain and source regions, wherein another portion may be provided as an in situ doped material with a reduced offset with respect to the gate electrode material. For this purpose, in one illustrative embodiment, a cyclic epitaxial growth process including a plurality of growth/etch cycles may be used at low temperatures in an ultra-high vacuum ambient, thereby obtaining a substantially bottom to top fill behavior.

Abstract: Three-dimensional transistor structures such as FinFETS and tri-gate transistors may be formed on the basis of an enhanced masking regime, thereby enabling the formation of drain and source areas, the fins and isolation structures in a self-aligned manner within a bulk semiconductor material. After defining the basic fin structures, highly efficient manufacturing techniques of planar transistor configurations may be used, thereby even further enhancing overall performance of the three-dimensional transistor configurations.

Abstract: A method of forming a field effect transistor comprises providing a semiconductor substrate, a gate electrode being formed over the semiconductor substrate. At least one cavity is formed adjacent the gate electrode. A strain-creating element is formed in the at least one cavity. The strain-creating element comprises a compound material comprising a first chemical element and a second chemical element. A first concentration ratio between a concentration of the first chemical element in a first portion of the strain-creating element and a concentration of the second chemical element in the first portion of the strain-creating element is different from a second concentration ratio between a concentration of the first chemical element in a second portion of the strain-creating element and a concentration of the second chemical element in the second strain-creating element.

Abstract: By forming a strained semiconductor layer in a PMOS transistor, a corresponding compressively strained channel region may be achieved, while, on the other hand, a corresponding strain in the NMOS transistor may be relaxed. Due to the reduced junction resistance caused by the reduced band gap of silicon/germanium in the NMOS transistor, an overall performance gain is accomplished, wherein, particularly in partially depleted SOI devices, the deleterious floating body effect is also reduced, due to the increased leakage currents generated by the silicon/germanium layer in the PMOS and NMOS transistor.

Abstract: By omitting a growth mask or by omitting lithographical patterning processes for forming growth masks, a significant reduction in process complexity may be obtained for the formation of different strained semiconductor materials in different transistor types. Moreover, the formation of individually positioned semiconductor materials in different transistors may be accomplished on the basis of a differential disposable spacer approach, thereby combining high efficiency with low process complexity even for highly advanced SOI transistor devices.

Abstract: By performing a heat treatment on the basis of a hydrogen ambient, exposed silicon-containing surface portions may be reorganized prior to the formation of gate dielectric materials. Hence, the interface quality and the material characteristics of the gate dielectrics may be improved, thereby reducing negative bias temperature instability effects in highly scaled P-channel transistors.

Abstract: By forming an etch control material with increased thickness on a first stressed dielectric layer in a dual stress liner approach, the surface topography may be smoothed prior to the deposition of the second stressed dielectric material, thereby allowing the deposition of an increased amount of stressed material while not contributing to yield loss caused by deposition-related defects.

Abstract: A strained semiconductor material may be positioned in close proximity to the channel region of a transistor, such as an SOI transistor, while reducing or avoiding undue relaxation effects of metal silicides and extension implantations, thereby providing enhanced efficiency for the strain generation.

Abstract: By forming an implantation mask prior to the definition of the drain and the source areas, an effective decoupling of the gate dopant concentration from that of the drain and source concentrations is achieved. Moreover, after removal of the implantation mask, the lateral dimension of the gate electrode may be defined by well-established sidewall spacer techniques, thereby providing a scaling advantage with respect to conventional approaches based on photolithography and anisotropic etching.

Abstract: A dislocation region is formed by implanting a light inert species, such as hydrogen, to a specified depth and with a high concentration, and by heat treating the inert species to create “nano” bubbles, which enable a certain mechanical decoupling to underlying device regions, thereby allowing a more efficient creation of strain that is induced by an external stress-generating source. In this way, strain may be created in a channel region of a field effect transistor by, for instance, a stress layer or sidewall spacers formed in the vicinity of the channel region.