Abstract: When forming high-k metal gate electrode structures by providing the gate dielectric material in an early manufacturing stage, the heat treatment or anneal process may be applied after incorporating work function metal species and prior to capping the gate dielectric material with a metal-containing electrode material. In this manner, the CET for a given physical thickness for the gate dielectric layer may be significantly reduced.

Abstract: A semiconductor device includes a plurality of NMOS transistor elements, each including a first gate electrode structure above a first active region, at least two of the plurality of first gate electrode structures including a first encapsulating stack having a first dielectric cap layer and a first sidewall spacer stack. The semiconductor device also includes a plurality of PMOS transistor elements, each including a second gate electrode structure above a second active region, wherein at least two of the plurality of second gate electrode structures include a second encapsulating stack having a second dielectric cap layer and a second sidewall spacer stack. Additionally, the first and second sidewall spacer stacks each include at least three dielectric material layers, wherein each of the three dielectric material layers of the first and second sidewall spacer stacks include the same dielectric material.

Abstract: When forming high-k metal gate electrode structures in transistors of different conductivity type while also incorporating an embedded strain-inducing semiconductor alloy selectively in one type of transistor, superior process uniformity may be accomplished by selectively reducing the thickness of a dielectric cap material of a gate layer stack above the active region of transistors which do not receive the strain-inducing semiconductor alloy. In this case, superior confinement and thus integrity of sensitive gate materials may be accomplished in process strategies in which the sophisticated high-k metal gate electrode structures are formed in an early manufacturing stage, while, in a replacement gate approach, superior process uniformity is achieved upon exposing the surface of a placeholder electrode material.

Abstract: When forming sophisticated semiconductor devices, three-dimensional transistors in combination with planar transistors may be formed on the basis of a replacement gate approach and self-aligned contact elements by forming the semiconductor fins in an early manufacturing stage, i.e., upon forming shallow trench isolations, wherein the final electrically effective height of the semiconductor fins may be adjusted after the provision of self-aligned contact elements and during the replacement gate approach.

Abstract: The work function of a high-k gate electrode structure may be adjusted in a late manufacturing stage on the basis of a lanthanum species in an N-channel transistor, thereby obtaining the desired high work function in combination with a typical conductive barrier material, such as titanium nitride. For this purpose, in some illustrative embodiments, the lanthanum species may be formed directly on the previously provided metal-containing electrode material, while an efficient barrier material may be provided in the P-channel transistor, thereby avoiding undue interaction of the lanthanum species in the P-channel transistor.

Abstract: Generally, the subject matter disclosed herein relates to sophisticated semiconductor devices and methods for forming the same, wherein the pitch between adjacent gate electrodes is aggressively scaled, and wherein self-aligning contact elements may be utilized to avoid the high electrical resistance levels commonly associated with narrow contact elements formed using typically available photolithography techniques. One illustrative embodiment includes forming first and second gate electrode structures above a semiconductor substrate, then forming a first layer of a first dielectric material adjacent to or in contact with the sidewalls of each of the first and second gate electrode structures.

Abstract: The work function of a high-k gate electrode structure may be adjusted in a late manufacturing stage on the basis of a lanthanum species in an N-channel transistor, thereby obtaining the desired high work function in combination with a typical conductive barrier material, such as titanium nitride. For this purpose, in some illustrative embodiments, the lanthanum species may be formed directly on the previously provided metal-containing electrode material, while an efficient barrier material may be provided in the P-channel transistor, thereby avoiding undue interaction of the lanthanum species in the P-channel transistor.

Abstract: When forming high-k metal gate electrode structures by providing the gate dielectric material in an early manufacturing stage, the heat treatment or anneal process may be applied after incorporating work function metal species and prior to capping the gate dielectric material with a metal-containing electrode material. In this manner, the CET for a given physical thickness for the gate dielectric layer may be significantly reduced.

Abstract: When forming sophisticated high-k metal gate electrode structures, the threshold voltage characteristics are adjusted on the basis of a well-established high-k dielectric material with an appropriate layer thickness, for instance by incorporating an appropriate metal species. Thereafter, further high-k dielectric materials may be deposited, typically with a greater dielectric constant, so as to define the final CET and physical thickness.

Abstract: When forming sophisticated circuit elements, such as transistors, capacitors and the like, using a combination of a conventional dielectric material and a high-k dielectric material, superior performance and reliability may be achieved by forming a hafnium oxide-based high-k dielectric material on a conventional dielectric layer with a preceding surface treatment, for instance using APM at room temperature. In this manner, sophisticated transistors of superior performance and with improved uniformity of threshold voltage characteristics may be obtained, while also premature failure due to dielectric breakdown, hot carrier injection and the like may be reduced.

Abstract: Sophisticated gate electrode structures may be formed by providing a cap layer including a desired species that may diffuse into the gate dielectric material prior to performing a treatment for stabilizing the sensitive gate dielectric material. In this manner, complex high-k metal gate electrode structures may be formed on the basis of reduced temperatures and doses for a threshold adjusting species compared to conventional strategies. Moreover, a single metal-containing electrode material may be deposited for both types of transistors.

Abstract: A method of switching a memristive device in a two-dimensional array senses a leakage current through the two-dimensional array when a voltage of half of a switching voltage is applied to a row line of the memristive device. A leakage compensation current is generated according to the sensed leakage current, and a switching current ramp is also generated. The leakage compensation current and the switching current ramp are combined to form a combined switching current, which is applied to the row line of the memristive device. When a resistance of the memristive device reaches a target value, the combined switching current is removed from the row line.

Abstract: In sophisticated approaches for forming high-k metal gate electrode structures in an early manufacturing stage, a threshold adjusting semiconductor alloy may be deposited on the basis of a selective epitaxial growth process without affecting the back side of the substrates. Consequently, any negative effects, such as contamination of substrates and process tools, reduced surface quality of the back side and the like, may be suppressed or reduced by providing a mask material and preserving the material at least during the selective epitaxial growth process.

Abstract: A switch element includes a switch device having a drain, a source and a plurality of gates, and at least one additional interconnect located between the plurality of gates, the additional interconnect operative to establish a constant potential between the at least two gates.

Abstract: When forming sophisticated gate electrode structures of transistor elements of different type, the threshold adjusting channel semiconductor alloy may be provided prior to forming isolation structures, thereby achieving superior uniformity of the threshold adjusting material. Consequently, threshold variability on a local and global scale of P-channel transistors may be significantly reduced.

Abstract: Sophisticated gate electrode structures for N-channel transistors and P-channel transistors are patterned on the basis of substantially the same configuration while, nevertheless, the work function adjustment may be accomplished in an early manufacturing stage. For this purpose, diffusion layer and cap layer materials are removed after incorporating the desired work function metal species into the high-k dielectric material and subsequently a common gate layer stack is deposited and subsequently patterned.

Abstract: When forming self-aligned contact elements in sophisticated semiconductor devices in which high-k metal gate electrode structures are to be provided on the basis of a replacement gate approach, the self-aligned contact openings are filled with an appropriate fill material, such as polysilicon, while the gate electrode structures are provided on the basis of a placeholder material that can be removed with high selectivity with respect to the sacrificial fill material. In this manner, the high-k metal gate electrode structures may be completed prior to actually filling the contact openings with an appropriate contact material after the removal of the sacrificial fill material. In one illustrative embodiment, the placeholder material of the gate electrode structures is provided in the form of a silicon/germanium material.

Abstract: In sophisticated transistor elements including a high-k gate metal stack, the integrity of the sensitive gate materials may be ensured by a spacer element that may be concurrently used as an offset spacer for defining a lateral offset of a strain-inducing semiconductor alloy. The cap material of the sophisticated gate stack may be removed without compromising integrity of the offset spacer by providing a sacrificial spacer element. Consequently, an efficient strain-inducing mechanism may be obtained in combination with the provision of a sophisticated gate stack with the required material integrity, while reducing overall process complexity compared to conventional strategies.

Abstract: When forming high-k metal gate electrode structures in transistors of different conductivity type while also incorporating an embedded strain-inducing semiconductor alloy selectively in one type of transistor, superior process uniformity may be accomplished by selectively reducing the thickness of a dielectric cap material of a gate layer stack above the active region of transistors which do not receive the strain-inducing semiconductor alloy. In this case, superior confinement and thus integrity of sensitive gate materials may be accomplished in process strategies in which the sophisticated high-k metal gate electrode structures are formed in an early manufacturing stage, while, in a replacement gate approach, superior process uniformity is achieved upon exposing the surface of a placeholder electrode material.

Abstract: During the formation of sophisticated gate electrode structures, a replacement gate approach may be applied in which plasma assisted etch processes may be avoided. To this end, one of the gate electrode structures may receive an intermediate etch stop liner, which may allow the replacement of the placeholder material and the adjustment of the work function in a later manufacturing stage. The intermediate etch stop liner may not negatively affect the gate patterning sequence.