A superstrate for planarizing a substrate. The superstrate includes a body having a first side having a contact surface and a second side having a central portion and a peripheral portion surrounding the central portion. The peripheral portion includes a recessed region.

A semiconductor structure and the manufacturing method thereof are disclosed. An exemplary semiconductor structure includes a first source/drain contact and a second source/drain contact spaced apart by a gate structure, an etch stop layer (ESL) over the first source/drain contact and the second source/drain contact, a conductive feature disposed in the etch stop layer and in direct contact with the first source/drain contact and the second source/drain contact, a dielectric layer over the etch stop layer, and a contact via extending through the dielectric layer and electrically connected to the conductive feature. By providing the conductive feature, a number of metal lines in an interconnect structure of the semiconductor structure may be advantageously reduced.

Examples are disclosed that relate to planarizing substrates without use of an abrasive. One example provides a method of chemically planarizing a substrate, the method comprising introducing an abrasive-free planarization solution onto a porous pad, contacting the substrate with the porous pad while moving the porous pad and substrate relative to one another such that higher portions of the substrate contact the porous pad and lower portions of the substrate do not contact the porous pad, and removing material from the higher portions of the substrate via contact with the porous pad to reduce a height of the higher portions of the substrate relative to the lower portions of the substrate.

In a method of manufacturing a semiconductor device, an underlying structure is formed over a substrate. A film is formed over the underlying structure. Surface topography of the film is measured and the surface topography is stored as topography data. A local etching is performed by using directional etching and scanning the substrate so that an entire surface of the film is subjected to the directional etching. A plasma beam intensity of the directional etching is adjusted according to the topography data.

Methods for seam-less gapfill comprising forming a flowable film by PECVD and curing the flowable film to solidify the film. The flowable film can be formed using a higher order silane and plasma. A UV cure, or other cure, can be used to solidify the flowable film.

A method of forming a semiconductor device includes forming a plurality of fins on a substrate, forming a polysilicon gate structure, and replacing the polysilicon gate structure with a metal gate structure. Replacing the polysilicon gate structure includes depositing a work function metal layer over the plurality of fins, forming a metal oxide layer over the work function metal layer, and depositing a first metal layer over the metal oxide layer. A first portion of the metal oxide layer is formed within an area between adjacent fins from among the plurality of fins. An example benefit includes reduced diffusion of unwanted and/or detrimental elements from the first metal layer into its underlying layers and consequently, the reduction of the negative impact of these unwanted and/or detrimental elements on the semiconductor device performance.

The present invention provides a method of manufacturing a fin field effect transistor, comprising: providing an SOI substrate comprising a substrate layer (100), a BOX layer (120) and an SOI layer (130); forming a basic fin structure from an SOI layer; forming source/drain regions (110) on both sides of the basic fin structure; forming a fin structure between the source/drain regions (110) from a basic fin structure; and forming a gate stack across the fin structure. The method of manufacturing a fin field effect transistor provided in the present invention can integrate a high-k gate dielectric layer, a metal gate, and stressed source/drain regions into the fin field effect transistor to enhance the performance of the semiconductor device.

A chemical mechanical polishing (CMP) composition (Q) for chemical mechanical polishing of a substrate (S) containing (i) cobalt and/or (ii) a cobalt alloy, wherein the CMP composition (Q) contains: (A) Inorganic particles, (B) a substituted aromatic compound with at least one carboxylic acid function as corrosion inhibitor, (C) at least one amino acid, (D) at least one oxidizer, (E) an aqueous medium, wherein the CMP composition (Q) has a pH of from 7 to 10.

A method of manufacturing a semiconductor device is provided. The semiconductor device includes a semiconductor substrate, first and second fins on the semiconductor substrate and separated by a trench. The first fin includes a first portion having a first conductivity type and a second portion having a second conductivity type different from the first conductivity type, the first and second portions are adjacent to each other, and the second portion connected to the second fin through the semiconductor substrate. The semiconductor device also includes a gate structure on the first and second portions and including a gate insulator layer on the first and second portions, a gate on a portion of the gate insulator layer on the first portion, and a dummy gate on the second portion and including an insulating layer or an undoped semiconductor layer and adjacent to the gate.

There is provided an integrated RF subsystem including a chip substrate, a circuit patterned on a first surface of the chip substrate, a probe electrically integrated with the circuit on a first side of the chip substrate, a frame at a second side of the chip substrate defining a first cavity underneath the circuit.