Abstract: A semiconductor device includes a first transistor positioned in and above a first semiconductor region, the first semiconductor region having a first upper surface and including a first semiconductor material. The semiconductor device further includes first raised drain and source portions positioned on the first upper surface of the first semiconductor region, the first drain and source portions including a second semiconductor material having a different material composition from the first semiconductor material. Additionally, the semiconductor device includes a second transistor positioned in and above a second semiconductor region, the second semiconductor region including the first semiconductor material. Finally, the semiconductor device also includes strain-inducing regions embedded in the second semiconductor region, the embedded strain-inducing regions including the second semiconductor material.

Abstract: When forming sophisticated gate electrode structures requiring a threshold adjusting semiconductor alloy for one type of transistor, a recess is formed in the corresponding active region, thereby providing superior process uniformity during the deposition of the semiconductor material. Moreover, the well dopant species is implanted after the recessing, thereby avoiding undue dopant loss. Due to the recess, any exposed sidewall surface areas of the active region may be avoided during the selective epitaxial growth process, thereby significantly contributing to enhanced threshold stability of the resulting transistor including the high-k metal gate stack.

Abstract: By forming an additional dielectric material, such as silicon nitride, after patterning dielectric liners of different intrinsic stress, a significant increase of performance of N-channel transistors may be obtained while substantially not contributing to a performance loss of the P-channel transistor.

Abstract: The PN junction of a substrate diode in a sophisticated SOI device may be formed on the basis of an embedded in situ doped semiconductor material, thereby providing superior diode characteristics. For example, a silicon/germanium 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: By providing a protection layer on a silicon/germanium material of high germanium concentration, a corresponding loss of strained semiconductor material may be significantly reduced or even completely avoided. The protection layer may be formed prior to critical cleaning processes and may be maintained until the formation of metal silicide regions. Hence, high performance gain of P-type transistors may be accomplished without requiring massive overfill during the selective epitaxial growth process.

Abstract: In SOI devices, the PN junction of circuit elements, such as substrate diodes, is formed in the substrate material on the basis of the buried insulating material that provides increased etch resistivity during wet chemical cleaning and etch processes. Consequently, undue exposure of the PN junction formed in the vicinity of the sidewalls of the buried insulating material may be avoided, which may cause reliability concerns in conventional SOI devices comprising a silicon dioxide material as the buried insulating layer.

Abstract: In sophisticated semiconductor devices, a strain-inducing embedded semiconductor alloy may be provided on the basis of a crystallographically anisotropic etch process and a self-limiting deposition process, wherein transistors which may not require an embedded strain-inducing semiconductor alloy may remain non-masked, thereby providing superior uniformity with respect to overall transistor configuration. Consequently, superior strain conditions may be achieved in one type of transistor, while generally reduced variations in transistor characteristics may be obtained for any type of transistors.

Abstract: Devices are formed with boot shaped source/drain regions formed by isotropic etching followed by anisotropic etching. Embodiments include forming a gate on a substrate, forming a first spacer on each side of the gate, forming a source/drain region in the substrate on each side of the gate, wherein each source/drain region extends under a first spacer, but is separated therefrom by a portion of the substrate, and has a substantially horizontal bottom surface. Embodiments also include forming each source/drain region by forming a cavity to a first depth adjacent the first spacer and forming a second cavity to a second depth below the first cavity and extending laterally underneath the first spacers.

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: In sophisticated semiconductor devices, an efficient adjustment of an intrinsic stress level of dielectric materials, such as contact etch stop layers, may be accomplished by selectively exposing the dielectric material to radiation, such as ultraviolet radiation. Consequently, different stress levels may be efficiently obtained without requiring sophisticated stress relaxation processes based on ion implantation, which typically leads to significant device failures.

Abstract: Embodiments of methods for fabricating the semiconductor devices are provided. The method includes forming a layer of spacer material over a semiconductor region that includes a first gate electrode structure and a second gate electrode structure. Carbon is introduced into a portion of the layer covering the semiconductor region about the first gate electrode structure or the second gate electrode structure. The layer is etched to form a first sidewall spacer about the first gate electrode structure and a second sidewall spacer about the second gate electrode structure.

Abstract: A method for forming a semiconductor device includes providing a substrate and depositing a gate stack having a side periphery on the substrate. A first liner dielectric layer is deposited on the substrate and the gate stack. A first spacer dielectric layer is deposited on the first liner dielectric layer. The first spacer dielectric layer is selectively etched such that the first spacer dielectric layer remains adjacent at least a portion of the side periphery of the gate stack. A first resist mask is disposed on a first portion of the first spacer dielectric layer such that the first portion of the first spacer dielectric layer is protected by the resist mask and a second portion of the first spacer dielectric layer is not protected by the resist mask. The first spacer dielectric layer is etched such that the second portion is removed and the first portion remains.

Abstract: By forming thermocouples in a contact structure of a semiconductor device, respective extension lines of the thermocouples may be routed to any desired location within the die, without consuming valuable semiconductor area in the device layer. Thus, an appropriate network of measurement points of interest may be provided, while at the same time allowing the application of well-established process techniques and materials. Hence, temperature-dependent signals may be obtained from hot spots substantially without being affected by design constraints in the device layer.

Abstract: Devices are formed with boot shaped source/drain regions formed by isotropic etching followed by anisotropic etching. Embodiments include forming a gate on a substrate, forming a first spacer on each side of the gate, forming a source/drain region in the substrate on each side of the gate, wherein each source/drain region extends under a first spacer, but is separated therefrom by a portion of the substrate, and has a substantially horizontal bottom surface. Embodiments also include forming each source/drain region by forming a cavity to a first depth adjacent the first spacer and forming a second cavity to a second depth below the first cavity and extending laterally underneath the first spacers.

Abstract: In MOS transistor elements, a strain-inducing semiconductor alloy may be embedded in the active region with a reduced offset from the channel region by applying a spacer structure of reduced width. In order to reduce the probability of creating semiconductor residues at the top area of the gate electrode structure, a certain degree of corner rounding of the semiconductor material may be introduced, which may be accomplished by ion implantation prior to epitaxially growing the strain-inducing semiconductor material. This concept may be advantageously combined with the provision of sophisticated high-k metal gate electrodes that are provided in an early manufacturing stage.

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: In sophisticated integrated circuits, an electronic fuse may be formed such that an increased sensitivity to electromigration may be accomplished by including at least one region of increased current density. This may be accomplished by forming a corresponding fuse region as a non-linear configuration, wherein at corresponding connection portions of linear segments, the desired enhanced current crowding may occur during the application of the programming voltage. Hence, increased reliability and more space-efficient layout of the electronic fuses may be accomplished.

Abstract: Embodiments of methods for fabricating the semiconductor devices are provided. The method includes forming a layer of spacer material over a semiconductor region that includes a first gate electrode structure and a second gate electrode structure. Carbon is introduced into a portion of the layer covering the semiconductor region about the first gate electrode structure or the second gate electrode structure. The layer is etched to form a first sidewall spacer about the first gate electrode structure and a second sidewall spacer about the second gate electrode structure.

Abstract: When forming sophisticated gate electrode structures in an early manufacturing stage, the threshold voltage characteristics may be adjusted on the basis of a semiconductor alloy, which may be formed on the basis of low pressure CVD techniques. In order to obtain a desired high band gap offset, for instance with respect to a silicon/germanium alloy, a moderately high germanium concentration may be provided within the semiconductor alloy, wherein, however, at the interface formed with the semiconductor base material, a low germanium concentration may significantly reduce the probability of creating dislocation defects.

Abstract: In integrated circuits, resistors may be formed on the basis of a silicon/germanium material, thereby providing a reduced specific resistance which may allow reduced dimensions of the resistor elements. Furthermore, a reduced dopant concentration may be used which may allow an increased process window for adjusting resistance values while also reducing overall cycle times.