The present application relates to a carbon dioxide snow cleaning apparatus comprising: a carbon dioxide source; a carbon dioxide snow nozzle in fluid communication with the carbon dioxide source; a charging element; and a collection surface. Also described is a method of cleaning a surface, the method comprising the steps of: (i) passing a stream of carbon dioxide out of a carbon dioxide snow nozzle to form a carbon dioxide snow stream; (ii) charging the carbon dioxide snow stream; (iii) directing the charged carbon dioxide snow stream onto the surface to be cleaned; (iv) collecting particles removed by the charged carbon dioxide snow stream from the surface to be cleaned on a collection surface. Also described is the use of such apparatus in a lithographic apparatus and the use of such an apparatus or method.

A stop, such as a numerical aperture stop, obscuration stop or false-light stop, for a lithography apparatus, includes a light-transmissive aperture and a stop element, in which or at which the aperture is provided. The stop element is opaque and fluid-permeable outside the aperture.

A lithography system and a cleaning method thereof are provided. The lithography system includes a light source generator. The light source generator includes a collector, a droplet generator and a droplet catcher. The droplet generator and the droplet catcher are facing each other, and disposed at a region surrounding the collector. The cleaning method includes: shifting the droplet generator out of the light source generator via a port of the light source generator; inserting a shove assembly into the light source generator via the port; using a borescope attached to the shovel assembly to identify a location of a deposit formed by droplets generated by the droplet generator; using the shovel assembly to remove and collect the deposit; and withdrawing the shovel assembly along with the borescope from the light source generator via the port.

An exposure device has a cylindrical peripheral wall member. The peripheral wall member forms a processing space in which a substrate is storable and has an upper opening and a lower opening. Further, a light emitter is provided in an upper portion of the peripheral wall member to close the upper opening. A lower lid member that is provided to be movable in an up-and-down direction and configured to be capable of closing and opening the lower opening is provided below the peripheral wall member. The atmosphere in the processing space is replaced with an inert gas with the substrate stored in the processing space and the lower opening closed by the lower lid member. In this state, vacuum ultraviolet rays are emitted to the substrate from the light emitter, and the substrate is exposed.

The present application relates to a carbon dioxide snow cleaning apparatus comprising: a carbon dioxide source; a carbon dioxide snow nozzle in fluid communication with the carbon dioxide source; a charging element; and a collection surface. Also described is a method of cleaning a surface, the method comprising the steps of: (i) passing a stream of carbon dioxide out of a carbon dioxide snow nozzle to form a carbon dioxide snow stream; (ii) charging the carbon dioxide snow stream; (iii) directing the charged carbon dioxide snow stream onto the surface to be cleaned; (iv) collecting particles removed by the charged carbon dioxide snow stream from the surface to be cleaned on a collection surface. Also described is the use of such apparatus in a lithographic apparatus and the use of such an apparatus or method.

An extreme ultraviolet (EUV) lithography system includes a vane bucket module. The vane bucket module includes a collecting tank and a temperature adjusting pack. The collecting tank has a cover and the cover includes a plurality of through holes. Thicknesses of edges of the cover is greater than a thickness of a center of the cover. The temperature adjusting pack surrounds the collecting tank. The temperature adjusting pack includes a plurality of inlets aligned with the through holes.

A method and apparatus for non-contact measurement of stress in a thin-film deposited on a substrate is disclosed. The method may include positioning a substrate on a plurality of support-elements, the substrate having a thin-film deposited thereupon. A first-polynomial may be defined for representing a surface of the substrate that is in contact with the support elements. A second-polynomial may be determined based on an optimization determination of potential-energy acting upon the substrate. A finite-order polynomial may be created by calculating a product of the first and second polynomials to represent a shape of the surface of the substrate as a model of the surface. Thereafter, stress in the substrate may be determined based on fitting the model of the surface with a measured topographical data of the surface.

An apparatus for removing residues from a source vessel in an extreme ultraviolet lithography device, the apparatus including a frame portion, and a heater structure on the frame portion, the heater structure having a head on the frame portion, the head being rotatable in at least one shaft direction, and a heater on the head to dissipate heat toward residues in the source vessel, the heater to apply temperature of 200° C. to 800° C.

A lithography system and a cleaning method thereof are provided. The lithography system includes a light source generator. The light source generator includes a collector, a droplet generator and a droplet catcher. The droplet generator and the droplet catcher are facing each other, and disposed at a region surrounding the collector. The cleaning method includes: shifting the droplet generator out of the light source generator via a port of the light source generator; inserting a shove assembly into the light source generator via the port; using a borescope attached to the shovel assembly to identify a location of a deposit formed by droplets generated by the droplet generator; using the shovel assembly to remove and collect the deposit; and withdrawing the shovel assembly along with the borescope from the light source generator via the port.

A method for producing a reflecting optical element for a projection exposure apparatus (1). The element has a substrate (30) with a substrate surface (31), a protection layer (38) and a layer partial system (39) suitable for the EUV wavelength range. The method includes: (a) measuring the substrate surface (31), (b) irradiating the substrate (30) with electrons (36), and (c) tempering the substrate (30). Furthermore, an associated reflective optical element for the EUV wavelength range, a projection lens with a mirror (18, 19, 20) as reflective optical element, and a projection exposure apparatus (1) including such a projection lens.