A method for detecting optical film defects based on differential interference, comprising: an incident light is adjusted into a planar light wave, and the surface of an optical film to be detected is adjusted to be perpendicular to the planar light wave; the planar light wave sequentially passes through a diaphragm, the optical film, a first collimating lens and a lenticular lens, and then form two parallel outgoing beams by differential interference; the two parallel outgoing beams pass through a second collimating lens to form a differential interference image on a photodetector; and the differential interference image is analyzed to detect both superficial and internal defects of the optical film.

Methods of inspecting a material include moving the material and identifying a defect location of a defect. Methods include moving a camera along a second travel path in a second travel direction such that a field of view (FOV) of the camera moves relative to the material along the second travel path to match the defect location. Methods include passing the defect through the field of view (FOV) as the material moves and capturing images of the defect with the camera as the material moves and the defect moves through the FOV. The images include a first image of a first major surface, a second image of a second major surface, and a third image of an intermediate portion of the material between the first major surface and the second major surface. Methods include reviewing the plurality of images to characterize the defect.

An optical scanning system includes a first radiating source capable of outputting a first source light beam, a second radiating source capable of outputting a second source light beam, a first time-varying beam reflector configured to direct the first source light beam and the second source light beam toward the sample, a scan lens configured to focus the first source light beam and the second source light beam reflected by the first time-varying beam reflector onto the sample, and a compound ellipsoidal collector configured to direct light scattered from the sample toward a scattered radiation detector. The optical scanning system causes one of the first or second source light beams to be directed towards a sample at an incident angle. The first light beam has a first wavelength, the second light beam has a second wavelength, and the first wavelength and the second wavelength are not the same.

An optical scanning system includes a radiating source capable of outputting a source light beam, a de-scan lens that is configured to output a de-scanned light beam, the de-scan lens is located approximately one focal length of the de-scan lens from a sample irradiation location, a focusing lens that is configured to output a focused light beam, a first non-polarizing beam splitter configured to be irradiated by at least a portion of the focused light beam, a second non-polarizing beam splitter configured to be irradiated by at least a portion of the focused light beam that is reflected by the first non-polarizing beam splitter, and a detector that is located at approximately one focal length of the focusing lens from the focusing lens, the detector is configured to be irradiated by at least a portion of the focused light beam that is reflected by the second non-polarizing beam splitter.

Preparation of anhydrous lithium sulfide (Li.sub.2S) purified suitably for applications in advanced batteries, and, in particular, for synthesis of solid electrolytes based on Li.sub.2S, including sulfide solid electrolytes of the type that may be described as crystalline (e.g., polycrystalline), amorphous (e.g., glass) and combinations thereof, such as sulfide glass-ceramic solid electrolyte materials.

A method for detecting optical film defects based on differential interference, comprising: an incident light is adjusted into a planar light wave, and the surface of an optical film to be detected is adjusted to be perpendicular to the planar light wave; the planar light wave sequentially passes through a diaphragm, the optical film, a first collimating lens and a lenticular lens, and then form two parallel outgoing beams by differential interference; the two parallel outgoing beams pass through a second collimating lens to form a differential interference image on a photodetector; and the differential interference image is analyzed to detect both superficial and internal defects of the optical film.

A method for defect inspection of a transparent substrate comprises utilizing a wavefront reconstruction unit to obtain complex defect diffraction wavefront of a transparent substrate; using a complex defect diffraction module to confirm the effective diffraction distance of the complex defect diffraction wavefront; utilizing a defect detection module to detect position of the defect of the transparent substrate; using a defect classification module to perform extraction, analysis and classification of diffraction characteristics and utilizing a machine learning algorithm or a deep learning algorithm to automatically identify the defects.

A method and/or system is provided for detecting and/or identifying inclusions (e.g., nickel sulfide based inclusions/defects) in glass such as soda-lime-silica based float glass. In certain example instances, during and/or after the glass-making process, following the stage in the float process where the glass sheet is formed and floated on a molten material (e.g., tin bath) and cooled or allowed to cool such as via an annealing lehr, energy such as infrared (IR) energy is directed at the resulting glass and reflectance at various wavelengths is analyzed to detect inclusions.

Methods for detecting defects on the surface of a sheet of material include collimating a beam of light and intersecting the collimated beam of light with a beam splitter. The beam splitter directs a first portion of the intersected beam of collimated light to illuminate a first surface of the sheet, wherein a first portion of the light illuminating the first surface is reflected and a second portion of the illuminating light is scattered by a defect. The reflected and scattered light is received with a first lens element that directs the reflected and scattered light to an inverse aperture. The reflected light is blocked by the inverse aperture and the scattered light is transmitted by the inverse aperture. The scattered light transmitted by the inverse aperture is directed with a second lens element to an imaging device.

An optical scanning system, including: a radiating source that outputs a light beam, a first time varying beam reflector that reflects the light beam through a scan lens towards a transparent sample, a second time varying beam reflector that reflects the light beam reflected from the transparent sample, a focusing lens that focuses the light beam reflected from the transparent sample, a blocker, and a detector that is irradiated by the one or more selectable portions of the light beam reflected from the transparent sample that pass the blocker. The blocker can be configured to block one or more portions of the light beam reflected from the transparent sample so that one or more selectable portions of the light beam reflected from the transparent sample can pass the blocker.