Abstract: Material erosion of trench isolation structures in advanced semiconductor devices may be reduced by incorporating an appropriate mask layer stack in an early manufacturing stage. For example, a silicon nitride material may be incorporated as a buried etch stop layer prior to a sequence for patterning active regions and forming a strain-inducing semiconductor alloy therein, wherein, in particular, the corresponding cleaning process prior to the selective epitaxial growth process has been identified as a major source for causing deposition-related irregularities upon depositing the interlayer dielectric material.

Abstract: By selectively applying a stress memorization technique to N-channel transistors, a significant improvement of transistor performance may be achieved. High selectivity in applying the stress memorization approach may be accomplished by substantially maintaining the crystalline state of the P-channel transistors while annealing the N-channel transistors in the presence of an appropriate material layer which may not to be patterned prior to the anneal process, thereby avoiding additional lithography and masking steps.

Abstract: In a static memory cell, the failure rate upon forming contact elements connecting an active region with a gate electrode structure formed above an isolation region may be significantly reduced by incorporating an implantation species at a tip portion of the active region through a sidewall of the isolation trench prior to filling the same with an insulating material. The implantation species may represent a P-type dopant species and/or an inert species for significantly modifying the material characteristics at the tip portion of the active region.

Abstract: The PN junction of a substrate diode in a sophisticated semiconductor device may be formed on the basis of an embedded in situ N-doped semiconductor material thereby providing superior diode characteristics. For example, a silicon/carbon semiconductor material may be formed in a cavity in the substrate material, wherein the size and shape of the cavity may be selected so as to avoid undue interaction with metal silicide material.

Abstract: In sophisticated P-channel transistors, a high germanium concentration may be used in a silicon/germanium alloy, wherein an additional semiconductor cap layer may provide enhanced process conditions during the formation of a metal silicide. For example, a silicon layer may be formed on the silicon/germanium alloy, possibly including a further strain-inducing atomic species other than germanium, in order to provide a high strain component while also providing superior conditions during the silicidation process.

Abstract: By introducing additional strain-inducing mechanisms on the basis of stress memorization techniques, the performance of NMOS transistors may be significantly increased, thereby reducing the imbalance between PMOS transistors and NMOS transistors. By amorphizing and re-crystallizing the respective material in the presence of a mask layer at various stages of the manufacturing process, a drive current improvement of up to approximately 27% has been observed, with the potential for further performance gain.

Abstract: A strain-inducing semiconductor alloy may be formed on the basis of cavities that may extend deeply below the gate electrode structure, which may be accomplished by using a sequence of two etch processes. In a first etch process, the cavity may be formed on the basis of a well-defined lateral offset to ensure integrity of the gate electrode structure and, in a subsequent etch process, the cavity may be increased in a lateral direction while nevertheless reliably preserving a portion of the channel region. Consequently, the strain-inducing efficiency may be increased by appropriately positioning the strain-inducing material immediately below the channel region without compromising integrity of the gate electrode structure.

Abstract: An efficient strain-inducing mechanism may be provided on the basis of a piezoelectric material so that performance of different transistor types may be enhanced by applying a single concept. For example, a piezoelectric material may be provided below the active region of different transistor types and may be appropriately connected to a voltage source so as to obtain a desired type of strain.

Abstract: The device degradation of integrated circuits may be compensated for by appropriately adapting the duty cycle of the clock signal. For this purpose, a correlation between the duty cycle and the overall performance characteristics of the integrated circuit may be established and may be used during the normal field operation of the device in order to modify the duty cycle. Hence, an efficient control strategy may be implemented since the duty cycle may be efficiently controlled, while at the same time a change of clock signal frequency and/or an increase of supply voltage may not be required.

Abstract: By maintaining a substantially constant total die power during the entire lifetime of sophisticated integrated circuits, the performance degradation may be reduced. Consequently, greatly reduced guard bands for parts classification may be used compared to conventional strategies in which significant performance degradation may occur when the integrated circuits are operated on the basis of a constant supply voltage.

Abstract: An asymmetric transistor configuration is disclosed in which asymmetric extension regions and/or halo regions may be combined with an asymmetric spacer structure which may be used to further adjust the overall dopant profile of the asymmetric transistor.

Abstract: By incorporating a diffusion hindering species at the vicinity of PN junctions of P-channel transistors comprising a silicon/germanium alloy, diffusion related non-uniformities of the PN junctions may be reduced, thereby contributing to enhanced device stability and increased overall transistor performance. The diffusion hindering species may be provided in the form of carbon, nitrogen and the like.

Abstract: Operation of complex integrated circuits at low temperatures may be enhanced by providing active heating elements within the integrated circuit so as to raise the temperature of at least critical circuit portions at respective operational phases, such as upon power-up. Consequently, enhanced cold temperature performance may be obtained on the basis of existing process elements in order to provide design stability without requiring extensive circuit simulation or redesign of well-established circuit architectures.

Abstract: By forming a single spacer element and reducing the size thereof by a well-controllable etch process, a complex lateral dopant profile may be obtained at reduced process complexity compared to conventional triple spacer approaches in forming drain and source regions of advanced MOS transistors.

Abstract: By selectively applying a stress memorization technique to N-channel transistors, a significant improvement of transistor performance may be achieved. High selectivity in applying the stress memorization approach may be accomplished by substantially maintaining the crystalline state of the P-channel transistors while annealing the N-channel transistors in the presence of an appropriate material layer which may not to be patterned prior to the anneal process, thereby avoiding additional lithography and masking steps.

Abstract: By removing material during the formation of trench openings of isolation structures in an SOI device, the subsequent implantation process for defining the well region for a substrate diode may be performed on the basis of moderately low implantation energies, thereby increasing process uniformity and significantly reducing cycle time of the implantation process. Thus, enhanced reliability and stability of the substrate diode may be accomplished while also providing a high degree of compatibility with conventional manufacturing techniques.

Abstract: By controlled increase of the supply voltage of sophisticated integrated circuits, the performance degradation over a lifetime may be significantly reduced. For this purpose, the upper limits of the supply voltage and the thermal design power are taken into consideration when increasing the supply voltage, which may then compensate for a typical performance degradation resulting in a more stable overall performance of integrated circuits. Thus, greatly reduced guard bands for parts classification may be used compared to conventional strategies.

Abstract: By removing an upper portion of a complex spacer structure, such as a triple spacer structure, an upper surface of an intermediate spacer element may be exposed, thereby enabling the removal of the outermost spacer and a material reduction of the intermediate spacer in a well-controllable common etch process. Consequently, sidewall portions of the gate electrode may be efficiently exposed for a subsequent silicidation process, while the residual reduced spacer provides sufficient process margins. Thereafter, highly stressed material may be deposited, thereby providing an enhanced stress transfer mechanism.

Abstract: By introducing additional strain-inducing mechanisms on the basis of stress memorization techniques, the performance of NMOS transistors may be significantly increased, thereby reducing the imbalance between PMOS transistors and NMOS transistors. By amorphizing and re-crystallizing the respective material in the presence of a mask layer at various stages of the manufacturing process, a drive current improvement of up to approximately 27% has been observed, with the potential for further performance gain.

Abstract: A new technique enables providing a stress-inducing alloy having a highly stress-inducing region and a region which is processable by standard processing steps suitable for use in a commercial high volume semiconductor device manufacturing environment. The regions may be formed by a growth process with a varying composition of the growing material or by other methods such as ion implantation. The highly stress-inducing region near the channel region of a transistor may be covered with an appropriate cover.