A method of making a mirror for use with extreme ultraviolet or x-ray radiation includes: i) providing a base substrate having a curved surface, wherein the curved surface deviates from a curvature of a target mirror surface at high spatial frequencies corresponding to spatial periods less than 2 mm; and ii) securing a first side of a thin plate to the curved surface of the base substrate to cover the curved surface, wherein the plate has a thickness thin enough to conform to the curvature of the target mirror surface and thick enough to attenuate deviations at the high spatial frequencies on a second side of the thin plate opposite the first side that are caused by the deviations on the curved surface of the base substrate. A mirror made by the method is also disclosed.

A metal grid includes: a valve metal plate which includes a curved principal surface; an anodic oxide film which is formed on the principal surface of the valve metal plate; and a lattice structure which has an uneven shape periodically formed on the anodic oxide film. Further, a production method for a metal grid includes: a step of bending a principal surface of a valve metal plate including the principal surface; a step of forming an anodic oxide film on the principal surface of the valve metal plate; and a step of forming a lattice structure with a periodic uneven shape on the anodic oxide film by forming an etching mask with a periodic opening on a surface of the anodic oxide film and etching the anodic oxide film through the opening.

An x-ray spectrometer system includes an x-ray source, an x-ray optical system, a mount, and an x-ray spectrometer. The x-ray optical system is configured to receive, focus, and spectrally filter x-rays from the x-ray source to form an x-ray beam having a spectrum that is attenuated in an energy range above a predetermined energy and having a focus at a predetermined focal plane.

The present invention relates to a hard X-ray photoelectron spectroscopy (HAXPES) system comprising an X-ray tube, an X-ray monochromator, and a sample. The X-ray tube provides a beam of photons, which via the X-ray monochromator is directed through the system so as to excite electrons from the illuminated sample. The X-ray tube is connected to a monochromator vacuum chamber in which the X-ray monochromator is configured to monochromatize and focus the beam onto the sample. The monochromator vacuum chamber is connected to an analysis vacuum chamber, the illuminated sample being mounted inside the analysis vacuum chamber and the analysis vacuum chamber being connected to an electron energy analyser. The electron energy analyser is mounted onto the analysis vacuum chamber. Further, the beam of photons provided from the X-ray tube is divergent and has an energy above 6 keV. The X-ray monochromator also comprises a curved optical element arranged to both monochromatize and focus the diverging beam of photons.

An example method for aligning a spectrometer is described herein. The spectrometer includes a radiation source, a crystal analyzer, and a detector that are all positioned on an instrument plane. The method includes rotating the crystal analyzer about an axis that is within the instrument plane and perpendicular to a rotation plane such that (i) a reciprocal lattice vector of the crystal analyzer is within the instrument plane or (ii) a component of the reciprocal lattice vector within the rotation plane is perpendicular to the instrument plane. An origin of the reciprocal lattice vector is located on the axis. The method further includes tilting the crystal analyzer or translating the detector such that the reciprocal lattice vector bisects a line segment that is bounded by the detector and the radiation source. Example spectrometers related to the example method are also disclosed.

A device includes a substrate and a stressed layer disposed on a first surface of the substrate. The stressed layer includes: a first set of patterns having a predetermined geometry, size, and arrangement selected to control an equibiaxial stress field of the stressed layer, wherein the equibiaxial stress field varies in magnitude over the first surface of the substrate, and a second set of patterns etched into the first set of patterns and the substrate, the second set of patterns comprising a plurality of substantially parallel lines arranged to control at least a uniaxial stress field of the stressed layer, wherein the uniaxial stress field varies in magnitude over the first surface of the substrate.

A spectrometer includes a crystal analyzer having a radius of curvature that defines a Rowland circle, a sample stage configured to support a sample such that the sample is offset from the Rowland circle, an x-ray source configured to emit unfocused x-rays toward the sample stage, and a position-sensitive detector that is tangent to the Rowland circle. A method performed via a spectrometer includes emitting, via an x-ray source, unfocused x-rays toward a sample that is mounted on a sample stage such that the sample is offset from the Rowland Circle, thereby causing the sample to emit x-rays that impinge on the crystal analyzer or transmit a portion of the unfocused x-rays to impinge on the crystal analyzer; scattering, via the crystal analyzer, the x-rays that impinge on the crystal analyzer; and detecting the scattered x-rays via a position-sensitive detector that is tangent to the Rowland circle.

The present invention relates to a hard X-ray photoelectron spectroscopy (HAXPES) system comprising an X-ray tube, an X-ray monochromator, and a sample. The X-ray tube provides a beam of photons, which via the X-ray monochromator is directed through the system so as to excite electrons from the illuminated sample. The X-ray tube is connected to a monochromator vacuum chamber in which the X-ray monochromator is configured to monochromatize and focus the beam onto the sample. The monochromator vacuum chamber is connected to an analysis vacuum chamber, the illuminated sample being mounted inside the analysis vacuum chamber and the analysis vacuum chamber being connected to an electron energy analyser. The electron energy analyser is mounted onto the analysis vacuum chamber.

Further, the beam of photons provided from the X-ray tube is divergent and has an energy above 6 keV. The X-ray monochromator also comprises a curved optical element arranged to both monochromatize and focus the diverging beam of photons.

Debris is removed from a collector of an extreme ultraviolet light source vessel by applying a suction force through a vacuum opening of a cable. The method for removing debris also includes weakening debris attachment by using a sticky surface or by spreading a solution through a nozzle, wherein the sticky surface and the nozzle are arranged on the cable proximal to the vacuum opening. A borescope system and interchangeable rigid portions of the cable assists in targeting a target area of the collector where the debris is.

An X-ray generation apparatus comprising: an X-ray generating unit; a dispersive crystal whose surface is irradiated with an X-ray generated from the X-ray generating unit in order to monochromatize the X-ray; and a detecting unit that detects an X-ray generated from a sample irradiated with the X-ray monochromatized by the dispersive crystal. The dispersive crystal has a single-bent shape containing the surface that is a concave surface formed by integrating concave curve lines continuously along an axis perpendicular to a plane including the concave curve line. A direction in which a position on the surface irradiated with the X-ray generated from the X-ray generating unit moves is the direction along the axis.