A method of manufacturing burr-edged reflecting tile elements for a mosaic X-ray lens configured for forming an X-ray beam comprises steps of: (a) providing a single crystal having first and second faces thereof being parallel therebetween; single crystal having crystallographic planes thereof being parallel to first and second faces of the single crystal; the first face dedicated for reflecting an X-ray beam to be incident thereto; (b) cutting the single crystal by means of a wire electrical discharging machine normally to the main faces. The step of cutting the single crystal comprises moving a wire within a cut in direction from the second face to the first face; such that burrs configured for reflecting the X-ray beam to be incident thereto are formed on edges of the cut.

A mirror including a substrate (110), a reflection layer system (120), and at least one continuous piezoelectric layer (130, . . . ) arranged between the substrate and the layer system. An electric field producing a locally variable deformation is applied to the piezoelectric layer via a first, layer-system-side electrode arrangement and a second, substrate-side electrode arrangement. At least one of the electrode arrangements is assigned a mediator layer (170) setting an at least regionally continuous profile of the electrical potential along the respective electrode arrangement. The electrode arrangement to which the mediator layer is assigned has a plurality of electrodes (160, . . . ), each of which is configured to receive an electrical voltage relative to the respective other electrode arrangement. In the region that couples two respectively adjacent electrodes, the mediator layer is subdivided into a plurality of regions (171, . . . ) that are electrically insulated from one another.

The invention described herein is a spectrometer having components allowing remote orientation of crystal analyzer and detector.

A chamber device may include a concentrating mirror, a central gas supply port, an inner wall, an exhaust port, a recessed portion, and a lateral gas supply port. The recessed portion may be on a side lateral to the focal line and recessed outward from the inner wall when viewed from a direction perpendicular to the focal line. The lateral gas supply port is formed at the recessed portion and may supply gas toward gas supplied from the central gas supply port so that a flow direction of the gas supplied from the central gas supply port is bent from a direction along the focal line toward the exhaust port and an internal space of the recessed portion.

A chamber device may include a concentrating mirror, a central gas supply port, an inner wall, an exhaust port, a recessed portion, and a lateral gas supply port. The recessed portion may be on a side lateral to the focal line and recessed outward from the inner wall when viewed from a direction perpendicular to the focal line. The lateral gas supply port is formed at the recessed portion and may supply gas toward gas supplied from the central gas supply port so that a flow direction of the gas supplied from the central gas supply port is bent from a direction along the focal line toward the exhaust port and an internal space of the recessed portion.

A method for applying a carbon-based reflective overcoating on a grazing incidence optical unit comprising a substrate and a coating of a high-density material chosen from the group comprising gold, platinum, iridium, palladium, rhodium, ruthenium, chrome and nickel or a low-density material such as carbon or B4C; the method comprises the step of treating the optical unit with a solution or gaseous phase containing at least one polymer precursor material to create the overcoating through absorption of the polymer material on the coating.

An extreme ultra violet (EUV) radiation source apparatus includes a collector mirror, a target droplet generator for generating a tin (Sn) droplet, a rotatable debris collection device, one or more coils for generating an inductively coupled plasma (ICP), a gas inlet for providing a source gas for the ICP, and a chamber enclosing at least the collector mirror and the rotatable debris collection device. The gas inlet and the one or more coils are configured such that the ICP is spaced apart from the collector mirror.

An extreme ultra violet (EUV) radiation source apparatus includes a collector mirror, a target droplet generator for generating a tin (Sn) droplet, a rotatable debris collection device, one or more coils for generating an inductively coupled plasma (ICP), a gas inlet for providing a source gas for the ICP, and a chamber enclosing at least the collector mirror and the rotatable debris collection device. The gas inlet and the one or more coils are configured such that the ICP is spaced apart from the collector mirror.

In a method for producing an optical element for an EUV projection exposure apparatus, a shaping layer (22.sub.1) is applied onto a substrate (20) so as to have a surface roughness of at most 0.5 nm rms directly after the application of the shaping layer onto the substrate.

A system for generating extreme ultraviolet light, in which a target material inside a chamber is irradiated with a laser beam to be turned into plasma, includes a first laser apparatus configured to output a first laser beam, a second laser apparatus configured to output a pedestal and a second laser beam, and a controller connected to the first and second laser apparatuses and configured to cause the first laser beam to be outputted first, the pedestal to be outputted after the first laser beam, and the second laser beam having higher energy than the pedestal to be outputted after the pedestal.