Techniques relate to forming a sorting device. A mesh is formed on top of a substrate. Metal assisted chemical etching is performed to remove substrate material of the substrate at locations of the mesh. Pillars are formed in the substrate by removal of the substrate material. The mesh is removed to leave the pillars in a nanopillar array. The pillars in the nanopillar array are designed with a spacing to sort particles of different sizes such that the particles at or above a predetermined dimension are sorted in a first direction and the particles below the predetermined dimension are sorted in a second direction.

The present application relates to a block copolymer and its use. The present application can provides a block copolymer that has an excellent self assembling property or phase separation property and therefore can be used in various applications and its use.

A cleaning agent is provided for a semiconductor substrate superior in corrosion resistance of a tungsten wiring or a tungsten alloy wiring, and superior in removal property of polishing fines (particle) such as silica or alumina, remaining at surface of the semiconductor substrate, in particular, at surface of a silicon oxide film such as a TEOS film, after a chemical mechanical polishing process; and a method for processing a semiconductor substrate surface. A cleaning agent for a semiconductor substrate is to be used in a post process of a chemical mechanical polishing process of the semiconductor substrate having a tungsten wiring or a tungsten alloy wiring, and a silicon oxide film, comprising (A) a phosphonic acid-based chelating agent, (B) a primary or secondary monoamine having at least one alkyl group or hydroxyalkyl group in a molecule and (C) water, wherein a pH is over 6 and below 7.

FinFET spacer formation includes, for example, providing an intermediate semiconductor structure having a substrate having one or more fin having a first and a second plurality of gates disposed thereon, and a first plurality of spacers disposed on sides of the first and second plurality of gates, depositing a first liner on the structure, depositing a fill material at a level along inner portions of the first liner between the gates adjacent to the one or more fin, removing outer portions of the first spacers and the first liner away from the fill material, the remaining portions of the first spacers and the first liner defining a first thickness, and depositing a second liner having a second thickness over the gates and over the remaining portions of the first spacers and the first liner, and the fill material, and wherein the first thickness is greater than the second thickness.

Embodiments of the invention provide a non-uniform substrate polishing apparatus that includes a polishing pad with two or more zones, each zone adapted to apply a different slurry chemistry to a different area on a substrate to create a film thickness profile on the substrate having at least two different film thicknesses. Polishing methods and systems adapted to polish substrates are also provided, as are numerous other aspects.

A method for forming nanowire semiconductor devices includes a) providing a substrate including an oxide layer defining vias; and b) depositing nanowires in the vias. The nanowires are made of a material selected from a group consisting of germanium or silicon germanium. The method further includes c) selectively etching back the oxide layer relative to the nanowires to expose upper portions of the nanowires; and d) doping the exposed upper portions of the nanowires using a dopant species.

The present application relates to a block copolymer and its use. The present application can provides a block copolymer that has an excellent self assembling property or phase separation property and therefore can be used in various applications and its use.

The present application relates to a block copolymer and uses thereof. The present application can provide a block copolymer—which exhibits an excellent self-assembling property and thus can be used effectively in a variety of applications—and uses thereof.

We disclose a semiconductor device, comprising a semiconductor substrate; at least one gate structure disposed above the semiconductor substrate, wherein the gate structure comprises a gate structure cavity partially filled with at least one metal layer; and an ultraviolet (UV) cured high density plasma (HDP) nitride cap layer in the gate structure cavity above the at least one metal layer. We also disclose at least one method and at least one system by which the semiconductor device may be formed. The UV cured HDP nitride cap layer may be substantially free of voids or seams, and as a result, the semiconductor device may have a reduced Vt shift relative to comparable semiconductor devices known in the art.

A device including a gap-fill layer may include an upper layer that on a lower layer that defines a trench that extends from a top surface of the upper layer and towards the lower layer, and the gap filling layer may be a multi-layered structure filling the trench. The gap-filling layer may include a first dielectric layer that fills a first portion of the trench and has a top surface proximate to the top surface of the upper layer, a second dielectric layer that fills a second portion of the trench and has a top surface proximate to the top surface of the upper layer and more recessed toward the lower layer than the top surface of the first dielectric layer, and a third dielectric layer that fills a remaining portion of the trench and covers the top surface of the second dielectric layer.