Abstract: The present disclosure is directed to, among other things, an illustrative method that includes forming an opening in a dielectric material of a contact level of a semiconductor device, and selectively depositing a conductive material in the opening to form a contact element therein, the contact element extending to a contact area of a circuit element and having a laterally restricted excess portion formed outside of the opening and above the dielectric material. The disclosed method further includes forming a sacrificial material layer above the dielectric material and the contact element, the sacrificial material layer surrounding the laterally restricted excess portion. Additionally, the method includes planarizing a surface topography of the contact level in the presence of the sacrificial material so as to remove the laterally restricted excess portion from above the dielectric material.

Abstract: Processes for forming an integrated circuit are provided. In an embodiment, a process for forming an integrated circuit includes forming a low-k dielectric layer overlying a base substrate. An etch mask is patterned over the low-k dielectric layer. A recess is etched into the low-k dielectric layer through the etch mask to expose a recess surface within the recess. The low-k dielectric layer and the base substrate are annealed after etching. Annealing is conducted in an annealing environment, such as in an annealing furnace that provides the annealing environment. The recess surface is exposed to the annealing environment. An electrically-conductive material is deposited in the recess after annealing to form an embedded electrical interconnect.

Abstract: A system and a method of operating a chemical mechanical polishing (CMP) system comprises a slurry delivering unit configured for locally varying the supply of slurry while polishing the substrate. To this end, the slurry delivering unit may comprise at least one slurry outlet over a polishing pad of the CMP system, wherein the at least one slurry outlet is controllably movable to distribute slurry over the polishing pad.

Abstract: The present disclosure is directed to, among other things, an illustrative method that includes forming an opening in a dielectric material of a contact level of a semiconductor device, and selectively depositing a conductive material in the opening to form a contact element therein, the contact element extending to a contact area of a circuit element and having a laterally restricted excess portion formed outside of the opening and above the dielectric material. The disclosed method further includes forming a sacrificial material layer above the dielectric material and the contact element, the sacrificial material layer surrounding the laterally restricted excess portion. Additionally, the method includes planarizing a surface topography of the contact level in the presence of the sacrificial material so as to remove the laterally restricted excess portion from above the dielectric material.

Abstract: Contact elements in the contact level of a semiconductor device may be formed on the basis of a selective deposition technique, such as electroless plating, wherein an efficient planarization of the contact level is achieved without subjecting the contact elements to undue mechanical stress. In some illustrative embodiments, an overfilling of the contact openings may be reliably avoided and the planarization of the surface topography is accomplished on the basis of a non-critical polishing process. In other cases, electrochemical etch techniques are applied in combination with a conductive sacrificial current distribution layer in order to remove any excess material of the contact elements without inducing undue mechanical stress.

Abstract: Contact elements in the contact level of a semiconductor device may be formed on the basis of a selective deposition technique, such as electroless plating, wherein an efficient planarization of the contact level is achieved without subjecting the contact elements to undue mechanical stress. In some illustrative embodiments, an overfilling of the contact openings may be reliably avoided and the planarization of the surface topography is accomplished on the basis of a non-critical polishing process. In other cases, electrochemical etch techniques are applied in combination with a conductive sacrificial current distribution layer in order to remove any excess material of the contact elements without inducing undue mechanical stress.

Abstract: A system and a method of operating a chemical mechanical polishing (CMP) system comprises a slurry delivering unit configured for locally varying the supply of slurry while polishing the substrate. To this end, the slurry delivering unit may comprise at least one slurry outlet over a polishing pad of the CMP system, wherein the at least one slurry outlet is controllably movable to distribute slurry over the polishing pad.

Abstract: A system and a method of operating a chemical mechanical polishing (CMP) system comprises a slurry delivering unit configured for locally varying the supply of slurry while polishing the substrate. To this end, the slurry delivering unit may comprise at least one slurry outlet over a polishing pad of the CMP system, wherein the at least one slurry outlet is controllably movable to distribute slurry over the polishing pad.

Abstract: By providing an eddy current sensor element in a polishing tool at a reduced height level in combination with a corresponding optical endpoint detection system, standard polishing pads may be used, thereby enhancing the lifetime of the polishing pad and increasing tool utilization.

Abstract: A system for chemical mechanical polishing (CMP) is disclosed which includes a polishing apparatus for polishing a surface of a substrate and a sensor for determining zone-specific substrate data respectively related to at least two zones of the substrate. A controller is provided for generating, in response to the zone-specific substrate data, at least one set-point value, e.g., a set-point window of values for at least one operating parameter of the polishing apparatus in a subsequent CMP process. The set-point value/set-point window of values may be displayed on a display device or automatically taken into account by the controller for controlling subsequent CMP processes.

Abstract: A system and a method of operating a chemical mechanical polishing (CMP) system comprises a slurry delivering unit configured for locally varying the supply of slurry while polishing the substrate. To this end, the slurry delivering unit may comprise at least one slurry outlet over a polishing pad of the CMP system, wherein the at least one slurry outlet is controllably movable to distribute slurry over the polishing pad.

Abstract: The present invention allows correcting malfunctions occurring in the formation of a cap layer on an electrical element in a semiconductor substrate. It is detected whether a malfunction occurred in the formation of the cap layer. If a malfunction in the formation of the cap layer was detected, a rework procedure is performed. The rework procedure can comprise exposing the substrate to a first acid and a second acid.

Abstract: In a system and a method according to the present invention, a sensor signal, such as a motor current signal, from a drive assembly of a pad conditioning system is used to control a CMP system to compensate for a change in the conditions of consumables, thereby enhancing process stability.