Abstract: A substrate processing method is provided for metal filling of recessed features in a substrate. According to one embodiment, the method includes providing a substrate containing horizontally spaced nested and isolated recessed features, filling the nested and isolated recessed features with a blocking material, and performing in any order: a) sequentially first, removing the blocking material from the nested recessed features, and second, filling the nested recessed features with a first metal, and b) sequentially first, removing the blocking material from the isolated recessed features, and second, filling the isolated recessed features with a second metal that is different from the first metal. According to one embodiment, the first metal may include Ru metal and the second metal may include Cu metal. According to one embodiment, a microelectronic device containing metal filled recessed features is provided.

Abstract: A semiconductor device is provided. The semiconductor device can have a substrate including dielectric material. A plurality of narrow interconnect openings can be formed within said dielectric material. In addition, a plurality of wide interconnect openings can be formed within said dielectric material. The semiconductor device can include a first metal filling the narrow interconnect openings to form an interconnect structure and conformally covering a surface of the wide interconnect openings formed in the dielectric material, and a second metal formed over the first metal and encapsulated by the first metal to form another interconnect structure within the wide interconnect openings.

Abstract: A semiconductor device is provided. The semiconductor device can have a substrate including dielectric material. A plurality of narrow interconnect openings can be formed within said dielectric material. In addition, a plurality of wide interconnect openings can be formed within said dielectric material. The semiconductor device can include a first metal filling the narrow interconnect openings to form an interconnect structure and conformally covering a surface of the wide interconnect openings formed in the dielectric material, and a second metal formed over the first metal and encapsulated by the first metal to form another interconnect structure within the wide interconnect openings.

Abstract: Multipath clock and data recovery circuits and multipath I/O devices are described that operate to provide flexible I/O paths for serial data communications. Active unidirectional components such as a clock and data recovery circuit may be used to implement different I/O paths. Bandwidth and signal degradation for high-speed serial data transmission is reduced.

Abstract: A removal method is provided for selectively removing a plurality of types of metal oxide films in a plurality of recesses formed in a substrate that is arranged in a processing chamber. The removal method includes repeatedly performing process steps of exposing the plurality of types of metal oxide films to BCl3 gas or a BCl3 gas plasma generated by introducing BCl3 gas, stopping introduction of the BCl3 gas and performing a purge process, exposing the plurality of types of metal oxide films and/or a plurality of types of metal films underneath the metal oxide films to one or more different plasmas, at least one of which is generated by introducing a single gas of an inert gas, and stopping introduction of the inert gas and performing the purge process.

Abstract: A method for forming a fully self-aligned via is provided. A workpiece having a pattern of features in a dielectric layer is received into a common manufacturing platform. Metal caps are deposited on the metal features, and a barrier layer is deposited on the metal caps. A first dielectric layer is added to exposed dielectric material. The barrier layer is removed and an etch stop layer is added on the exposed surfaces of the first dielectric layer and the metal caps. Additional dielectric material is added on top of the etch stop layer, then both the additional dielectric material and a portion of the etch stop layer are etched to form a feature to be filled with metal material. An integrated sequence of processing steps is executed within one or more common manufacturing platforms to provide controlled environments. Transfer modules transfer the workpiece between processing modules within and between controlled environments.

Abstract: A method of processing materials on a semiconductor workpiece using an integrated sequence of processing steps executed on a common manufacturing platform hosting a plurality of processing modules including one or more film-forming modules, one or more etching modules, and one or more transfer modules is provided. A workpiece having an upper planar surface is received into the common manufacturing platform. The method further includes conformally applying a thin film over the feature pattern using one of the film-forming modules, removing the thin film from upper surfaces of the feature pattern using one of the etching modules to leave behind the thin film in the recessed feature, and removing the fill material from the upper planar surface of the workpiece. The integrated sequence of processing steps is executed in a controlled environment within the common manufacturing platform and without leaving the controlled environment.

Abstract: A method for forming a fully self-aligned via is provided. A workpiece having a pattern of features in a dielectric layer is received into a common manufacturing platform. Metal caps are deposited on the metal features, and a barrier layer is deposited on the metal caps. A first dielectric layer is added to exposed dielectric material. The barrier layer is removed and an etch stop layer is added on the exposed surfaces of the first dielectric layer and the metal caps. Additional dielectric material is added on top of the etch stop layer, then both the additional dielectric material and a portion of the etch stop layer are etched to form a feature to be filled with metal material. An integrated sequence of processing steps is executed within one or more common manufacturing platforms to provide controlled environments. Transfer modules transfer the workpiece between processing modules within and between controlled environments.

Abstract: Repeaters are described that operate to rapidly transition from low-power standby states to a low frequency signal transmission state. Bandwidth for high-frequency signal transmission is preserved.

Abstract: Repeaters are described that operate to rapidly transition from low-power standby states to a low frequency signal transmission state. Bandwidth for high-frequency signal transmission is preserved.

Abstract: A semiconductor device includes a plurality of first sources/drains and a plurality of first source/drain (S/D) contacts formed over the first sources/drains. The device also includes a plurality of first dielectric caps. Each of the plurality of first dielectric caps is positioned over a respective first S/D contact to cover a top portion and at least a part of side portions of the respective first S/D contact. The device also includes a plurality of second sources/drains and a plurality of second S/D contacts that are staggered over the plurality of first S/D contacts so as to form a stair-case configuration. A plurality of second dielectric caps are formed over the plurality of second S/D contacts. Each of the plurality of second dielectric caps is positioned over a respective second S/D contact to cover a top portion and at least a part of side portions of the respective second S/D contact.

Abstract: Methods are described for protecting cobalt (Co) metal plugs used for making electrical connections within a semiconductor device. In one example, method includes providing a substrate containing a Co metal plug in a dielectric layer, and selectively forming a ruthenium (Ru) metal cap layer on the Co metal plug. In another example, the method includes providing a substrate containing a Co metal plug in a first dielectric layer, selectively forming a Ru metal cap layer on the Co metal plug, depositing a second dielectric layer on the Ru metal cap layer and on the first dielectric layer, etching a recessed feature in the second dielectric layer to expose the Ru metal cap layer, and performing a cleaning process that removes polymer etch residue from the Ru metal cap layer in the recessed feature.

Abstract: Embodiments of the invention provide methods for selective deposition on different materials using a surface treatment. According to one embodiment, the method includes providing a substrate containing a first material layer having a first surface and a second material layer having a second surface, and performing a chemical oxide removal process that terminates that second surface with hydroxyl groups. The method further includes modifying the second surface by exposure to a process gas containing a hydrophobic functional group, the modifying substituting the hydroxyl groups on the second surface with the hydrophobic functional group, and selectively depositing a metal-containing layer on the first surface but not on the modified second surface by exposing the substrate to a deposition gas.

Abstract: Embodiments are disclosed for a method to process microelectronic workpieces including forming a metal hard mask layer including ruthenium (Ru MHM layer) over one or more underlying layers on a substrate for a microelectronic workpiece, etching the Ru MHM layer to provide a patterned Ru MHM layer, and etching the one or more underlying layers using the patterned Ru MHM layer as a mask to protect portion of the one or more underlying layers. For one embodiment, the Ru MHM layer is a material including 95 percent or more of ruthenium (Ru). For another embodiment, the Ru MHM layer is a material including 70 percent or more of ruthenium (Ru). Further, the Ru MHM layer preferably has a selectivity of 10 or greater with respect to a next underlying layer adjacent to the Ru MHM layer, such as a SiN hard mask layer.

Abstract: A removal method is provided for selectively removing a plurality of types of metal oxide films in a plurality of recesses formed in a substrate that is arranged in a processing chamber. The removal method includes repeatedly performing process steps of exposing the plurality of types of metal oxide films to BCl3 gas or a BCl3 gas plasma generated by introducing BCl3 gas, stopping introduction of the BCl3 gas and performing a purge process, exposing the plurality of types of metal oxide films and/or a plurality of types of metal films underneath the metal oxide films to one or more different plasmas, at least one of which is generated by introducing a single gas of an inert gas, and stopping introduction of the inert gas and performing the purge process.

Abstract: Referenceless clock and data recovery circuits are described that operate to align the clock/data strobe with each data eye to achieve a low bit error rate. The appropriate frequency and phase to be used is determined by an edge counter based frequency error detector and a phase error detector.

Abstract: A method is provided for void-free Ru metal filling of features in a substrate. The method includes providing a substrate containing features, depositing a Ru metal layer in the features, removing the Ru metal layer from a field area around an opening of the features, and depositing additional Ru metal in the features, where the additional Ru metal is deposited in the features at a higher rate than on the field area. According to one embodiment, the additional Ru metal is deposited until the features are fully filled with Ru metal.

Abstract: Referenceless clock and data recovery circuits are described that operate to align the clock/data strobe with each data eye to achieve a low bit error rate. The appropriate frequency and phase to be used is determined by an edge counter based frequency error detector and a phase error detector.

Abstract: Methods for integration of conformal barrier layers and Ru metal liners with Cu metallization in semiconductor manufacturing are described in several embodiments. According to one embodiment, the method includes providing a substrate containing a recessed feature, depositing a barrier layer in the recessed feature, depositing a Ru metal liner on the barrier layer, and exposing the substrate to an oxidation source gas to oxidize the barrier layer through the Ru metal liner. The method further includes filling the recessed feature with CuMn metal using an ionized physical vapor deposition (IPVD) process, heat-treating the substrate to diffuse Mn from the CuMn metal to the oxidized barrier layer, and reacting the diffused Mn with the oxidized barrier layer to form a Mn-containing diffusion barrier.

Abstract: A substrate processing method is provided for metal filling of recessed features in a substrate. According to one embodiment, the method includes providing a substrate containing horizontally spaced nested and isolated recessed features, filling the nested and isolated recessed features with a blocking material, and performing in any order: a) sequentially first, removing the blocking material from the nested recessed features, and second, filling the nested recessed features with a first metal, and b) sequentially first, removing the blocking material from the isolated recessed features, and second, filling the isolated recessed features with a second metal that is different from the first metal. According to one embodiment, the first metal may include Ru metal and the second metal may include Cu metal. According to one embodiment, a microelectronic device containing metal filled recessed features is provided.