Abstract: A method of manufacturing an integrated circuit device is provided. A first feature, which has a first susceptibility to damage by chemical mechanical processing (CMP), is formed at a first height as measured from an upper surface of the substrate. A second feature, which has a second susceptibility to damage by the CMP, is formed at a second height as measured from the upper surface of the substrate and is laterally spaced from the first feature by a recess. The second height is greater than the first height, and the second susceptibility is less than the first susceptibility. A sacrificial coating is formed in the recess over an uppermost surface of the first feature. CMP is performed to remove a first portion of the sacrificial coating and expose an upper surface of the second feature while leaving a second portion of the sacrificial coating in place over the first feature.

Abstract: An IC device manufacturing process effectuates a planar recessing of material that initially varies in height across a substrate. The method includes forming a polymer coating, CMP to form a planar surface, then plasma etching to effectuate a planar recessing of the polymer coating. The material can be recessed together with the polymer coating, or subsequently with the recessed polymer coating providing a mask. Any of the material above a certain height is removed. Structures that are substantially below that certain height can be protected from contamination and left intact. The polymer can be a photoresist. The polymer can be provided with suitable adhesion and uniformity for the CMP process through a two-step baking process and by exhausting the baking chamber from below the substrate.

Abstract: The present disclosure provides a method of manufacturing an integrated circuit device in some embodiments. In the method, a semiconductor substrate is processed through a series of operations to form a topographically variable surface over the semiconductor substrate. The topographically variable surface varies in height across the semiconductor substrate. A polymeric bottom anti-reflective coating (BARC) is provided over the topographically variable surface. Chemical mechanical polishing is performed to remove a first portion of the BARC, and etching effectuates a top-down recessing of the BARC.

Abstract: An IC device manufacturing process effectuates a planar recessing of material that initially varies in height across a substrate. The method includes forming a polymer coating, CMP to form a planar surface, then plasma etching to effectuate a planar recessing of the polymer coating. The material can be recessed together with the polymer coating, or subsequently with the recessed polymer coating providing a mask. Any of the material above a certain height is removed. Structures that are substantially below that certain height can be protected from contamination and left intact. The polymer can be a photoresist. The polymer can be provided with suitable adhesion and uniformity for the CMP process through a two-step baking process and by exhausting the baking chamber from below the substrate.

Abstract: The present disclosure provides a method of manufacturing an integrated circuit device in some embodiments. In the method, a semiconductor substrate is processed through a series of operations to form a topographically variable surface over the semiconductor substrate. The topographically variable surface varies in height across the semiconductor substrate. A polymeric bottom anti-reflective coating (BARC) is provided over the topographically variable surface. Chemical mechanical polishing is performed to remove a first portion of the BARC, and etching effectuates a top-down recessing of the BARC.

Abstract: An IC device manufacturing process effectuates a planar recessing of material that initially varies in height across a substrate. The method includes forming a bottom anti-reflective coating (BARC), baking to induce cross-linking in the BARC, CMP to remove a first portion of the BARC and form a planar surface, then plasma etching to effectuate a planar recessing of the BARC. The plasma etching can have a low selectivity between the BARC and the material being recessed, whereby the BARC and the material are recessed simultaneously. Any of the material above a certain height is removed. Structures that are substantially below that certain height can be protected from contamination and left intact. The method can be particularly effective when an abrasive used during CMP forms ester linkages with the BARC.

Abstract: One or more semiconductor devices are provided. The semiconductor device comprises a gate body, a conductive prelayer over the gate body, at least one inhibitor film over the conductive prelayer and a conductive layer over the at least one inhibitor film, where the conductive layer is tapered so as to have a top portion width that is greater than the bottom portion width. One or more methods of forming a semiconductor device are also provided, where an etching process is performed to form a tapered opening such that the tapered conductive layer is formed in the tapered opening.

Abstract: An IC device manufacturing process effectuates a planar recessing of material that initially varies in height across a substrate. The method includes forming a bottom anti-reflective coating (BARC), baking to induce cross-linking in the BARC, CMP to remove a first portion of the BARC and form a planar surface, then plasma etching to effectuate a planar recessing of the BARC. The plasma etching can have a low selectivity between the BARC and the material being recessed, whereby the BARC and the material are recessed simultaneously. Any of the material above a certain height is removed. Structures that are substantially below that certain height can be protected from contamination and left intact. The method can be particularly effective when an abrasive used during CMP forms ester linkages with the BARC.