In a method of manufacturing a semiconductor device, in an EUV scanner, an EUV lithography operation using an EUV mask is performed on a photo resist layer formed over a semiconductor substrate. After the EUV lithography operation, the EUV mask is unloaded from a mask stage of the EUV scanner. The EUV mask is placed under a reduced pressure below an atmospheric pressure. The EUV mask is heated under the reduced pressure at a first temperature in a range from 100° C. to 350 C°. After the heating, the EUV mask is stored in a mask stocker.

A method includes transporting a cleaning mask and a photomask into an enclosure of a lithography exposure apparatus, wherein the photomask includes a multilayered mirror structure, and the cleaning mask is free of the multilayered mirror structure; placing the cleaning mask on a reticle stage of the lithography exposure apparatus; and charging the cleaning mask to attract charged particles in the enclosure.

An EUV collector mirror for an extreme ultra violet (EUV) radiation source apparatus includes an EUV collector mirror body on which a reflective layer as a reflective surface is disposed, a heater attached to or embedded in the EUV collector mirror body and a drain structure to drain melted metal from the reflective surface of the EUV collector mirror body to a back side of the EUV collector mirror body.

The present application relates to contact immersion lithography exposure units and methods of their use. An example contact exposure unit includes a container configured to contain a fluid material and a substrate disposed within the container. The substrate has a first surface and a second surface, and the substrate includes a photoresist material on at least the first surface. The contact exposure unit includes a photomask disposed within the container. The photomask is optically coupled to the photoresist material by way of a gap comprising the fluid material. The contact exposure unit also includes an inflatable balloon configured to be controllably inflated so as to apply a desired force to the second surface of the substrate to controllably adjust the gap between the photomask and the photoresist material.

The invention relates to a method for removing particles from a mask system for a projection exposure apparatus, comprising the following method steps: detecting the particle in the mask system, providing laser radiation, removing the particle by irradiating the particle with laser radiation.

According to the invention, the wavelength of the laser radiation corresponds to that of used radiation used by the projection exposure apparatus.

A method of operating a semiconductor apparatus includes generating an electric field in peripheral areas of a first covering structure and a second covering structure; causing a photomask to move to a position between the first and second covering structures such that the photomask at least partially vertically overlaps the first and second covering structures and such that particles attached to the photomask are attracted to the first and second covering structures by the electric field; and irradiating the photomask with light through light transmission regions of the first and second covering structures.

The present application relates to contact immersion lithography exposure units and methods of their use. An example contact exposure unit includes a container configured to contain a fluid material and a substrate disposed within the container. The substrate has a first surface and a second surface, and the substrate includes a photoresist material on at least the first surface. The contact exposure unit includes a photomask disposed within the container. The photomask is optically coupled to the photoresist material by way of a gap comprising the fluid material. The contact exposure unit also includes an inflatable balloon configured to be controllably inflated so as to apply a desired force to the second surface of the substrate to controllably adjust the gap between the photomask and the photoresist material.

A cleaning apparatus for cleaning a surface of a photomask includes a housing defining a chamber, a photomask holder disposed within the chamber, and a gas dispenser disposed within the chamber to direct gas toward the photomask holder. The gas dispenser has two or more gas dispensing outlets. A driver is coupled to at least one of the photomask holder or the gas dispenser to establish relative movement between the photomask holder and the gas dispenser.

Apparatus for processing substrates can include a gas distribution plate that includes an upper plate and a lower plate and a solid disk between the upper plate and the lower plate. Each of the upper plate and the lower plate has a central region and an outer region surrounding the central region, the central region being solid and the outer region having a plurality of through holes. The upper plate and the lower plate are coaxially aligned along a central axis extending through a center of the central region of the upper plate and a center of the central region of the lower plate. The solid disk is coaxially aligned with the upper plate and the lower plate. The solid disk is configured to block transmission of ultraviolet radiation through the solid disk.

In a method of cleaning a lithography system, during idle mode, a stream of air is directed, through a first opening, into a chamber of a wafer table of an EUV lithography system. One or more particles is extracted by the directed stream of air from surfaces of one or more wafer chucks in the chamber of the wafer table. The stream of air and the extracted one or more particle are drawn, through a second opening, out of the chamber of the wafer table.