Abstract: An x-ray mirror optic includes a plurality of surface segments with quadric cross-sections having differing quadric parameters. The quadric cross-sections of the surface segments share a common axis and are configured to reflect x-rays in a plurality of reflections along a single optical axis or in a scattering plane defined as containing an incident x-ray and a corresponding reflected x-ray.

Abstract: An apparatus includes a crystal analyzer positioned relative to an x-ray source on a Rowland circle in a tangential plane and having a Rowland circle radius (R). The crystal analyzer includes crystal planes curved along at least one direction within at least the tangential plane with a radius of curvature substantially equal to twice the Rowland circle radius (2R). The crystal planes are configured to receive x-rays from the x-ray source and to disperse the received x-rays according to Bragg's law. The apparatus further includes a spatially resolving detector configured to receive at least a portion of the dispersed x-rays. The spatially resolving detector includes a plurality of x-ray detection elements having a tunable first x-ray energy and/or a tunable second x-ray energy.

Abstract: An x-ray imaging/inspection system includes an x-ray source having a plurality of sub-sources in thermal communication with a substrate. The system further includes a first grating positioned to receive at least some of the x-rays from the x-ray source, a stage configured to hold a sample positioned to receive at least some of the x-rays from the x-ray source, at least one x-ray detector, and a second grating having periodic structures. The x-ray source, the first grating, and the second grating are configured such that a ratio of a pitch p0 of the plurality of sub-sources to a pitch p2 of the periodic structures of the second grating is substantially equal to a ratio of a distance dS-G1 between the plurality of sub-sources and the first grating and a distance dG1-G2 between the first grating and the second grating: (p0/p2)=(dS-G1/dG1-G2).

Abstract: An x-ray source includes an anode assembly having at least one surface configured to rotate about an axis, the at least one surface in a first region. The x-ray source further includes an electron-beam source configured to emit at least one electron beam configured to bombard the at least one surface of the anode assembly. The electron-beam source includes a housing, a cathode assembly, and a window. The housing at least partially bounds a second region and comprises an aperture. The cathode assembly is configured to generate the at least one electron beam within the second region. The window is configured to hermetically seal the aperture, to maintain a pressure differential between the first region and the second region, and to allow the at least one electron beam to propagate from the second region to the first region.

Abstract: A system and a method use x-ray fluorescence to analyze a specimen by illuminating a specimen with an incident x-ray beam having a near-grazing incident angle relative to a surface of the specimen and while the specimen has different rotational orientations relative to the incident x-ray beam. Fluorescence x-rays generated by the specimen in response to the incident x-ray beam are collected while the specimen has the different rotational orientations.

Abstract: An x-ray mirror optic includes a plurality of surface segments with quadric cross-sections having differing quadric parameters. The quadric cross-sections of the surface segments share a common axis and are configured to reflect x-rays in a plurality of reflections along a single optical axis or in a scattering plane defined as containing an incident x-ray and a corresponding reflected x-ray.

Abstract: A system for x-ray analysis includes at least one x-ray source configured to emit x-rays. The at least one x-ray source includes at least one silicon carbide sub-source on or embedded in at least one thermally conductive substrate and configured to generate the x-rays in response to electron bombardment of the at least one silicon carbide sub-source. At least some of the x-rays emitted from the at least one x-ray source includes Si x-ray emission line x-rays. The system further includes at least one x-ray optical train configured to receive the Si x-ray emission line x-rays and to irradiate a sample with at least some of the Si x-ray emission line x-rays.

Abstract: An x-ray spectrometer includes at least one x-ray optic configured to receive x-rays having an incident intensity distribution as a function of x-ray energy and at least one x-ray detector configured to receive x-rays from the at least one x-ray optic and to record a spatial distribution of the x-rays from the at least one x-ray optic. The at least one x-ray optic includes at least one substrate having at least one surface extending at least partially around and along a longitudinal axis. A distance between the at least one surface and the longitudinal axis in at least one cross-sectional plane parallel to the longitudinal axis varies as a function of position along the longitudinal axis. The at least one x-ray optic further includes at least one mosaic crystal structure and/or a plurality of layers on or over at least a portion of the at least one surface.

Abstract: An x-ray target, x-ray source, and x-ray system are provided. The x-ray target includes a thermally conductive substrate comprising a surface and at least one structure on or embedded in at least a portion of the surface. The at least one structure includes a thermally conductive first material in thermal communication with the substrate. The first material has a length along a first direction parallel to the portion of the surface in a range greater than 1 millimeter and a width along a second direction parallel to the portion of the surface and perpendicular to the first direction. The width is in a range of 0.2 millimeter to 3 millimeters. The at least one structure further includes at least one layer over the first material. The at least one layer includes at least one second material different from the first material. The at least one layer has a thickness in a range of 2 microns to 50 microns. The at least one second material is configured to generate x-rays upon irradiation by electrons.

Abstract: 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.

Abstract: An x-ray optical filter includes at least one x-ray optical mirror configured to receive a plurality of x-rays having a first x-ray spectrum with a first intensity as a function of energy in a predetermined solid angle range and to separate at least some of the received x-rays by multilayer reflection or total external reflection into reflected x-rays and non-reflected x-rays and to form an x-ray beam including at least some of the reflected x-rays and/or at least some of the non-reflected x-rays. The x-ray beam has a second x-ray spectrum with a second intensity as a function of energy in the solid angle range, the second intensity greater than or equal to 50% of the first intensity across a first continuous energy range at least 3 keV wide, the second intensity less than or equal to 10% of the first intensity across a second continuous energy range at least 100 eV wide.

Abstract: A system and a method use x-ray fluorescence to analyze a specimen by illuminating a specimen with an incident x-ray beam having a near-grazing incident angle relative to a surface of the specimen and while the specimen has different rotational orientations relative to the incident x-ray beam. Fluorescence x-rays generated by the specimen in response to the incident x-ray beam are collected while the specimen has the different rotational orientations.

Abstract: An x-ray source includes an anode assembly having at least one surface configured to rotate about an axis, the at least one surface in a first region. The x-ray source further includes an electron-beam source configured to emit at least one electron beam configured to bombard the at least one surface of the anode assembly. The electron-beam source includes a housing, a cathode assembly, and a window. The housing at least partially bounds a second region and comprises an aperture. The cathode assembly is configured to generate the at least one electron beam within the second region.

Abstract: An energy-resolving x-ray detection system is provided, the system including at least one x-ray optic configured to receive x-rays having an energy bandwidth with a maximum x-ray energy. The at least one x-ray optic has at least one concave surface extending at least partially around and along a longitudinal axis. The at least one concave surface is curved in at least one cross-sectional plane parallel to the longitudinal axis and is configured to direct at least some of the received x-rays into at least one convergent x-ray beam having a minimum beam width in a plane perpendicular to the longitudinal axis. The minimum beam width is at a location and the at least one concave surface has an x-ray reflectivity less than 30% for x-rays having energies greater than one-third of the maximum x-ray energy. The system further includes at least one energy-dispersive x-ray detector configured to receive at least a portion of the at least one convergent x-ray beam.

Abstract: A target for generating x-rays includes at least one substrate including a first material and a plurality of discrete structures including at least one second material configured to generate x-rays in response to electron bombardment. The discrete structures are distributed across a first surface of the at least one substrate in an array pattern function A that has a corresponding function B such that a combination operation of the array pattern function A with the corresponding function B generates a resultant function C comprising a first portion with a single peak and a substantially flat second portion surrounding the first portion.

Abstract: An x-ray target, x-ray source, and x-ray system are provided. The x-ray target includes a thermally conductive substrate comprising a surface and at least one structure on or embedded in at least a portion of the surface. The at least one structure includes a thermally conductive first material in thermal communication with the substrate. The first material has a length along a first direction parallel to the portion of the surface in a range greater than 1 millimeter and a width along a second direction parallel to the portion of the surface and perpendicular to the first direction. The width is in a range of 0.2 millimeter to 3 millimeters. The at least one structure further includes at least one layer over the first material. The at least one layer includes at least one second material different from the first material. The at least one layer has a thickness in a range of 2 microns to 50 microns. The at least one second material is configured to generate x-rays upon irradiation by electrons.

Abstract: An x-ray target, x-ray source, and x-ray system are provided. The x-ray target includes a thermally conductive substrate comprising a surface and at least one structure on or embedded in at least a portion of the surface. The at least one structure includes a thermally conductive first material in thermal communication with the substrate. The first material has a length along a first direction parallel to the portion of the surface in a range greater than 1 millimeter and a width along a second direction parallel to the portion of the surface and perpendicular to the first direction. The width is in a range of 0.2 millimeter to 3 millimeters. The at least one structure further includes at least one layer over the first material. The at least one layer includes at least one second material different from the first material. The at least one layer has a thickness in a range of 2 microns to 50 microns.

Abstract: An x-ray imaging system includes an x-ray source, a beam-splitting grating having a plurality of structures arranged in a two-dimensional periodic array, a stage configured to hold an object to be imaged, and an x-ray detector having a two-dimensional array of x-ray detecting elements and positioned to detect x-rays diffracted by the beam-splitting grating and perturbed by the object to be imaged.

Abstract: An x-ray source and an x-ray interferometry system utilizing the x-ray source are provided. The x-ray source includes a target that includes a substrate and a plurality of structures. The substrate includes a thermally conductive first material and a first surface. The plurality of structures is on or embedded in at least a portion of the first surface. The structures are separate from one another and are in thermal communication with the substrate. The structures include at least one second material different from the first material, the at least one second material configured to generate x-rays upon irradiation by electrons having energies in an energy range of 0.5 keV to 160 keV. The x-ray source further includes an electron source configured to generate the electrons and to direct the electrons to impinge the target and to irradiate at least some of the structures along a direction that is at a non-zero angle relative to a surface normal of the portion of the first surface.

Abstract: An x-ray interferometric imaging system in which the x-ray source comprises a target having a plurality of structured coherent sub-sources of x-rays embedded in a thermally conducting substrate. The system additionally comprises a beam-splitting grating G1 that establishes a Talbot interference pattern, which may be a ? phase-shifting grating, and an x-ray detector to convert two-dimensional x-ray intensities into electronic signals. The system may also comprise a second analyzer grating G2 that may be placed in front of the detector to form additional interference fringes, a means to translate the second grating G2 relative to the detector. The system may additionally comprise an antiscattering grid to reduce signals from scattered x-rays. Various configurations of dark-field and bright-field detectors are also disclosed.