Abstract: An apparatus and method for mapping film thickness of textured polycrystalline thin films. Multiple sample films of known thicknesses are provided, and each is irradiated by x-ray at a measurement point to generate a diffraction image that captures a plurality of diffraction arcs. Texture information (i.e., pole densities) of each sample film is calculated based on multiple incomplete pole figures collected from the diffraction image and used to correct the x-ray diffraction intensities obtained from such sample film. Corrected and integrated diffraction intensities of the sample films are then correlated to respective known film thicknesses of such films, and the correlation so determined can be used to map the film thickness of a textured polycrystalline thin film of unknown thickness, based on the corrected and integrated diffraction intensity calculated for such thin film.

Abstract: An apparatus and method for mapping film thickness of one or more textured polycrystalline thin films. Multiple sample films of known thickness are provided. Each sample film is irradiated by x-ray at a measurement point to generate a diffraction image that captures a plurality of diffraction arcs. Texture information (i.e., pole densities) of the sample film, is calculated based on incomplete pole figures collected on the diffraction image and used to correct the x-ray diffraction intensities from such sample. The corrected diffraction intensities are integrated for each sample film, and then used for constructing a calibration curve that correlates diffraction intensities with respective known film thickness of the sample films. The film thickness of a textured polycrystalline thin film of unknown thickness can therefore be mapped on such calibration curve, using a corrected and integrated diffraction intensity obtained for such thin film of unknown thickness.

Abstract: An apparatus and method for mapping film thickness of textured polycrystalline thin films. Multiple sample films of known thicknesses are provided, and each is irradiated by x-ray at a measurement point to generate a diffraction image that captures a plurality of diffraction arcs. Texture information (i.e., pole densities) of each sample film is calculated based on multiple incomplete pole figures collected from the diffraction image and used to correct the x-ray diffraction intensities obtained from such sample film. Corrected and integrated diffraction intensities of the sample films are then correlated to respective known film thicknesses of such films, and the correlation so determined can be used to map the film thickness of a textured polycrystalline thin film of unknown thickness, based on the corrected and integrated diffraction intensity calculated for such thin film.

Abstract: An apparatus and method for mapping film thickness of one or more textured polycrystalline thin films. Multiple sample films of known thickness are provided. Each sample film is irradiated by x-ray at a measurement point to generate a diffraction image that captures a plurality of diffraction arcs. Texture information (i.e., pole densities) of the sample film, is calculated based on incomplete pole figures collected on the diffraction image and used to correct the x-ray diffraction intensities from such sample. The corrected diffraction intensities are integrated for each sample film, and then used for constructing a calibration curve that correlates diffraction intensities with respective known film thickness of the sample films. The film thickness of a textured polycrystalline thin film of unknown thickness can therefore be mapped on such calibration curve, using a corrected and integrated diffraction intensity obtained for such thin film of unknown thickness.

Abstract: A method for quantitatively determining the phase composition of a sample mixture that comprises two or more textured polycrystalline materials, based on corrected and integrated x-ray diffraction intensities. The effect of texture has been analytically eliminated from such corrected and integrated x-ray diffraction intensities, based on the texture information obtained from the sample mixture.

Abstract: The present invention is directed to polymineralic particles which are precursors of hydroxyapatite and a method for their production. The present invention is also directed to a synthetic bone-like composition comprising said hydroxyapatite polymineralic precursor particles of hydroxyapatite and optionally, a polymeric material capable of promoting mineralization of hydroxyapatite, which are useful for fixing prosthetic devices, useful as bone substitutes to directly fill bone defects, to provide substrates for cartilage, and to repair teeth, and methods of making such preparations. The present invention is also directed to a method of treating collagen to provide a micro-structure close to that of native bone.