Abstract: A spacer structure in sophisticated semiconductor devices is formed on the basis of a high-k dielectric material, which provides superior etch resistivity compared to conventionally used silicon dioxide liners. Consequently, a reduced thickness of the etch stop material may nevertheless provide superior etch resistivity, thereby reducing negative effects, such as dopant loss in the drain and source extension regions, creating a pronounced surface topography and the like, as are typically associated with conventional spacer material systems.

Abstract: Sophisticated gate stacks including a high-k dielectric material and a metal-containing electrode material may be covered by a protection liner, such as a silicon nitride liner, which may be maintained throughout the entire manufacturing sequence at the bottom of the gate stacks. For this purpose, a mask material may be applied prior to removing cap materials and spacer layers that may be used for encapsulating the gate stacks during the selective epitaxial growth of a strain-inducing semiconductor alloy. Consequently, enhanced integrity may be maintained throughout the entire manufacturing sequence, while at the same time one or more lithography processes may be avoided.

Abstract: The present disclosure relates to semiconductor devices and a process sequence in which a semiconductor alloy, such as silicon/germanium, may be formed in an early manufacturing stage, wherein other performance-increasing mechanisms, such as a recessed drain and source configuration, possibly in combination with high-k dielectrics and metal gates, may be incorporated in an efficient manner while still maintaining a high degree of compatibility with conventional process techniques.

Abstract: A lattice distortion may be achieved by incorporating a hydrogen species into a semiconductor material, such as silicon, without destroying the lattice structure. For example, by incorporating the hydrogen species on the basis of an electron shower, a tensile strain component may be obtained in the channel of N-channel transistors.

Abstract: The present disclosure relates to semiconductor devices and a process sequence in which a semiconductor alloy, such as silicon/germanium, may be formed in an early manufacturing stage, wherein other performance-increasing mechanisms, such as a recessed drain and source configuration, possibly in combination with high-k dielectrics and metal gates, may be incorporated in an efficient manner while still maintaining a high degree of compatibility with conventional process techniques.

Abstract: In the process sequence for replacing conventional gate electrode structures by high-k metal gate structures, the number of additional masking steps may be maintained at a low level, for instance by using highly selective etch steps, thereby maintaining a high degree of compatibility with conventional CMOS techniques. Furthermore, the techniques disclosed herein enable compatibility to front-end process techniques and back-end process techniques, thereby allowing the integration of well-established strain-inducing mechanisms in the transistor level as well as in the contact level.

Abstract: By patterning a spacer layer stack and etching a cavity in an in situ etch process, the process complexity, as well as the uniformity, during the formation of embedded strained semiconductor layers may be significantly enhanced. In an initial phase, the spacer layer stack may be patterned on the basis of an anisotropic etch step with a high degree of uniformity, since a selectivity between individual stack layers may not be necessary. Thereafter, a cleaning process may be performed followed by a cavity etch process, wherein a reduced over-etch time during the spacer patterning process significantly contributes to the uniformity of the finally obtained cavities, while the in situ nature of the process also provides a reduced overall process time.

Abstract: By patterning a spacer layer stack and etching a cavity in an in situ etch process, the process complexity, as well as the uniformity, during the formation of embedded strained semiconductor layers may be significantly enhanced. In an initial phase, the spacer layer stack may be patterned on the basis of an anisotropic etch step with a high degree of uniformity, since a selectivity between individual stack layers may not be necessary. Thereafter, a cleaning process may be performed followed by a cavity etch process, wherein a reduced over-etch time during the spacer patterning process significantly contributes to the uniformity of the finally obtained cavities, while the in situ nature of the process also provides a reduced overall process time.

Abstract: A technique is provided that may be used to improve optical endpoint detection in a plasma etch process. A semiconductor structure is manufactured that includes at least one electrical device. The technique is adapted for forming a signal layer on or in a wafer, wherein the signal layer comprises a chemical element that causes a characteristic optical emission when coming into contact with an etch plasma. The chemical element does not have a primary influence on the electrical properties of the electrical device. The signal layer is for use in a plasma etch process to detect a plasma etch endpoint if the characteristic optical emission is detected. The signal layer may be patterned and may be incorporated into a stop layer.

Abstract: The present invention discloses a technique for controlling a local etch rate in forming multi-level contact openings, for example, in forming substrate contact openings and transistor contact openings of an SOI device. The aspect ratio dependent etch rate is correspondingly adapted by selecting in advance suitable aspect ratios for the contact openings so that the etch front may reach the respective final depth within a limited time interval.

Abstract: In a method and in a controller for an advanced process control one or more currently valid process states are stored and are compared, upon the occurrence of a reset event, with a subsequent valid process state that has been established after the re-initialization of the process controller. Upon comparison of the previously established process state, including the associated history information to the process state established after occurrence of the reset event on the basis of the newly gathered history information, it is decided whether or not a reset of the process controller has been necessary. If it is assessed that a reset has not been necessary, process control is continued on the basis of the previously established process state and possibly the presently valid process state and the relevant history information.

Abstract: A highly localized diffusion barrier is incorporated into a polysilicon line to allow the doping of the polysilicon layer without sacrificing an underlying material layer. The diffusion barrier is formed by depositing a thin polysilicon layer and exposing the layer to a nitrogen-containing plasma ambient. Thereafter, the deposition is resumed to obtain the required final thickness. Moreover, a polysilicon line is disclosed, having a highly localized barrier layer.

Abstract: In a system and a method for controlling critical dimensions of features to be formed on a substrate, a measurement device is coupled to an etch tool to form a feedback loop to control the critical dimensions on a wafer basis instead of a lot basis. In a further embodiment, the etch tool is in communication with a control unit that allows controlling of the etch tool and/or of the photolithography tool on the basis of an etch model. Thus, variations within a lot may be compensated by a software implementation of the etch model. The control unit may be implemented in the etch tool or an external device.

Abstract: The present invention discloses a technique for controlling a local etch rate in forming multi-level contact openings, for example, in forming substrate contact openings and transistor contact openings of an SOI device. The aspect ratio dependent etch rate is correspondingly adapted by selecting in advance suitable aspect ratios for the contact openings so that the etch front may reach the respective final depth within a limited time interval.

Abstract: A technique is disclosed that enables the formation of a highly conductive tungsten-containing substrate contact, wherein a lower portion of the substrate contact is formed prior to the formation of the circuit elements, and wherein an upper portion is formed along with contact plugs connecting to the circuit element in a common manufacturing process.

Abstract: A plasma control apparatus, a plasma etch system and a method of controlling plasma parameters in a production process are provided that may be used for performing real time measurements that relate to at least one physical or chemical property of a plasma. Learning data is generated that indicates at least one expected range for process run data. Process run data is received during the production process, wherein the process run data indicates current values of at least one plasma parameter. The plasma parameter of the production process is controlled based on the received process run data and the learning data.

Abstract: A technique is provided that may be used to improve optical endpoint detection in a plasma etch process. A semiconductor structure is manufactured that includes at least one electrical device. The technique is adapted for forming a signal layer on or in a wafer, wherein the signal layer comprises a chemical element that causes a characteristic optical emission when coming into contact with an etch plasma. The chemical element does not have a primary influence on the electrical properties of the electrical device. The signal layer is for use in a plasma etch process to detect a plasma etch endpoint if the characteristic optical emission is detected. The signal layer may be patterned and may be incorporated into a stop layer.

Abstract: A metrology tool, such as a scanning electron microscope, includes a control unit that calculates the dimension of a feature on the basis of a plurality of measurement results obtained with different resolution conditions. A mathematical function may be determined that represents the measurement results and an extreme value of the function may be calculated to obtain a final dimension of the feature. The actual dimension may thus be estimated more precisely than by a single measurement with an automatically determined “optimum” resolution of the metrology tool.

Abstract: A semiconductor device structure comprises a corner structure enclosed by a delineation region, wherein the shape of the corner structure does not exhibit any symmetry with respect to point symmetry and axial symmetry, such that the corner structure is unambiguously recognizable by an automated alignment system. Furthermore, the inner region of the corner structure may be filled with a pattern indicating the type of material layer in which the corner structure is formed. The corner structure exhibits a strong contrast even if the wafer is subjected to a CMP treatment.

Abstract: A highly localized diffusion barrier is incorporated into a polysilicon line to allow the doping of the polysilicon layer without sacrificing an underlying material layer. The diffusion barrier is formed by depositing a thin polysilicon layer and exposing the layer to a nitrogen-containing plasma ambient. Thereafter, the deposition is resumed to obtain the required final thickness. Moreover, a polysilicon line is disclosed, having a highly localized barrier layer.