Abstract: Structures for a field-effect transistor and methods for forming a structure for a field-effect transistor. A gate cavity is formed in a dielectric layer that includes a bottom surface and a plurality sidewalls that extend to the bottom surface. A gate dielectric layer is formed at the sidewalls and the bottom surface of the gate cavity. A work function metal layer is deposited on the gate dielectric layer at the sidewalls and the bottom surface of the gate cavity. A fill metal layer is deposited inside the gate cavity after the work function metal layer is deposited. The fill metal layer is formed in direct contact with the work function metal layer.

Abstract: Certain aspects of the present disclosure generally relate to wireless communication. In some aspects, a user equipment may receive extended access barring (EAB) information indicating whether the UE is subject to EAB. The UE may output an indication of whether the UE is subject to EAB based at least in part on receiving the EAB information. Numerous other aspects are provided.

Abstract: The present disclosure relates to semiconductor structures and, more particularly, to replacement metal gate structures and methods of manufacture. The structure includes at least one short channel device including a dielectric material, a workfunction metal, and a capping material, and a long channel device comprising the dielectric material, the workfunction metal and fluorine free gate conductor material.

Abstract: A method of fabricating advanced multi-threshold field effect transistors using a replacement metal gate process. A first method includes thinning layers composed of multilayer film stacks and incorporating a portion of the remaining thinned film in some transistors. A second method includes patterning dopant materials for a high-k dielectric by using thinning layers composed of multilayer thin film stacks, or in other embodiments, by a single thinning layer.

Abstract: Embodiments of the present invention provide a process that maintains a “keep cap” metal nitride layer on PFET devices within a CMOS structure. The keep cap metal nitride layer is in place while an N-type work function metal is formed on the NFET devices within the CMOS structure. A sacrificial rare earth oxide layer, such as a lanthanum oxide layer is used to facilitate removal of the n-type work function metal selective to the keep cap metal nitride layer.

Abstract: A method of fabricating multi Vth devices and the resulting device are disclosed. Embodiments include forming a high-k dielectric layer over a substrate; forming a first TiN layer, a first barrier layer, a second TiN layer, a second barrier layer, and a third TiN layer consecutively over the high-k dielectric layer; forming a first masking layer over the third TiN layer in a first region; removing the third TiN layer in second and third regions, exposing the second barrier layer in the second and third regions; removing the first masking layer; removing the exposed second barrier layer; forming a second masking layer over the third TiN layer in the first region and the second TiN layer in the second region; removing the second TiN layer in the third region, exposing the first barrier layer in the third region; removing the second masking layer; and removing the exposed first barrier layer.

Abstract: Semiconductor structures and methods of fabricating the same using interrupted deposition processes and multiple laser anneals are provided. The structure includes a high-k gate stack with a high-k bilayer or nanolaminate where a bottom portion of the bilayer is crystallized while a top portion of the bilayer is amorphous.

Abstract: Semiconductor structures and methods of fabricating the same using interrupted deposition processes and multiple laser anneals are provided. The structure includes a high-k gate stack with a high-k bilayer or nanolaminate where a bottom portion of the bilayer is crystallized while a top portion of the bilayer is amorphous.

Abstract: Methods of operating switching power supplies are disclosed. A power supply has a transformer and a switch coupled to the primary side of the transformer for controlling the current flow through the primary side of the transformer. A method includes determining the output voltage of the power supply. A first minimum switching frequency is generated for driving the switch in response to the output voltage being greater than a nominal output voltage and less than a predetermined voltage. A second minimum switching frequency is generated for driving the switch in response to the output voltage being equal to or greater than the predetermined voltage, wherein the first minimum switching frequency is greater than the second minimum switching frequency.

Abstract: A method of fabricating advanced node field effect transistors using a replacement metal gate process. The method includes dopant a high-k dielectric directly or indirectly by using layers composed of multi-layer thin film stacks, or in other embodiments, by a single blocking layer. By taking advantage of unexpected etch selectivity of the multi-layer stack or the controlled etch process of a single layer stack, etch damage to the high-k may be avoided and work function metal thicknesses can be tightly controlled which in turn allows field effect transistors with low Tinv (inverse of gate capacitance) mismatch.

Abstract: A method of fabricating multi Vth devices and the resulting device are disclosed. Embodiments include forming a high-k dielectric layer over a substrate; forming a first TiN layer, a first barrier layer, a second TiN layer, a second barrier layer, and a third TiN layer consecutively over the high-k dielectric layer; forming a first masking layer over the third TiN layer in a first region; removing the third TiN layer in second and third regions, exposing the second barrier layer in the second and third regions; removing the first masking layer; removing the exposed second barrier layer; forming a second masking layer over the third TiN layer in the first region and the second TiN layer in the second regions; removing the second TiN layer in the third region, exposing the first barrier layer in the third region; removing the second masking layer; and removing the exposed first barrier layer.

Abstract: A data processing system employs a pre-processing step to create a simplified view of a received entity graph. During the pre-processing step, only the objects and the attributes of those objects within the graph that are required for data processing are selected. Pruned source and target objects are generated by omitting those attributes that are not required for processing. The pruned objects are included in the simplified view that enhances system performance.

Abstract: Semiconductor device fabrication methods are provided which include: providing a structure with at least one region and including a dielectric layer disposed over a substrate; forming a multilayer stack structure including a threshold-voltage adjusting layer over the dielectric layer, the multilayer stack structure including a first threshold-voltage adjusting layer in a first region of the at least one region, and a second threshold-voltage adjusting layer in a second region of the at least one region; and annealing the structure to define a varying threshold voltage of the at least one region, the annealing facilitating diffusion of at least one threshold voltage adjusting species from the first threshold-voltage adjusting layer and the second threshold-voltage adjusting layer into the dielectric layer, where a threshold voltage of the first region is independent of the threshold voltage of the second region.

Abstract: Semiconductor device fabrication methods are provided which include: providing a structure with at least one region and including a dielectric layer disposed over a substrate; forming a multilayer stack structure including a threshold-voltage adjusting layer over the dielectric layer, the multilayer stack structure including a first threshold-voltage adjusting layer in a first region of the at least one region, and a second threshold-voltage adjusting layer in a second region of the at least one region; and annealing the structure to define a varying threshold voltage of the at least one region, the annealing facilitating diffusion of at least one threshold voltage adjusting species from the first threshold-voltage adjusting layer and the second threshold-voltage adjusting layer into the dielectric layer, where a threshold voltage of the first region is independent of the threshold voltage of the second region.

Abstract: A semiconductor structure includes a semiconductor substrate, n-type and p-type FinFETs on the substrate, each of the n-type and the p-type FinFETs include a channel region and a gate structure surrounding the channel region, each gate structure having a phase-changed high-k gate dielectric layer lining a gate trench thereof, the gate trench defined by a pair of spacers. The semiconductor structure further includes a conformal dielectric capping layer over each phase-changed high-k gate dielectric layer, the conformal dielectric capping layer having a higher dielectric constant than the phase-changed high-k gate dielectric layer. Further included on the n-type FinFETs is a multi-layer replacement gate stack of n-type work function material over the phase-changed high-k gate dielectric layer. A method of fabricating the semiconductor structure is also provided.

Abstract: Methods of operating switching power supplies are disclosed. A power supply has a transformer and a switch coupled to the primary side of the transformer for controlling the current flow through the primary side of the transformer. A method includes determining the output voltage of the power supply. A first minimum switching frequency is generated for driving the switch in response to the output voltage being greater than a nominal output voltage and less than a predetermined voltage. A second minimum switching frequency is generated for driving the switch in response to the output voltage being equal to or greater than the predetermined voltage, wherein the first minimum switching frequency is greater than the second minimum switching frequency.

Abstract: A method of fabricating advanced node field effect transistors using a replacement metal gate process. The method includes dopant a high-k dielectric directly or indirectly by using layers composed of multi-layer thin film stacks, or in other embodiments, by a single blocking layer. By taking advantage of unexpected etch selectivity of the multi-layer stack or the controlled etch process of a single layer stack, etch damage to the high-k may be avoided and work function metal thicknesses can be tightly controlled which in turn allows field effect transistors with low Tinv (inverse of gate capacitance) mismatch.

Abstract: Selective deposition of a silicon-germanium surface layer on semiconductor surfaces can be employed to provide two types of channel regions for field effect transistors. Anneal of an adjustment oxide material on a stack of a silicon-based gate dielectric and a high dielectric constant (high-k) gate dielectric can be employed to form an interfacial adjustment oxide layer contacting a subset of channel regions. Oxygen deficiency can be induced in portions of the high-k dielectric layer overlying the interfacial adjustment oxide layer by deposition of a first work function metallic material layer and a capping layer and a subsequent anneal. Oxygen deficiency can be selectively removed by physically exposing portions of the high-k dielectric layer. A second work function metallic material layer and a gate conductor layer can be deposited and planarized to form gate electrodes that provide multiple effective work functions.

Abstract: Semiconductor structures and methods of fabricating the same using interrupted deposition processes and multiple laser anneals are provided. The structure includes a high-k gate stack with a high-k bilayer or nanolaminate where a bottom portion of the bilayer is crystallized while a top portion of the bilayer is amorphous.

Abstract: Semiconductor structures and methods of fabricating the same using interrupted deposition processes and multiple laser anneals are provided. The structure includes a high-k gate stack with a high-k bilayer or nanolaminate where a bottom portion of the bilayer is crystallized while a top portion of the bilayer is amorphous.