Abstract: Example embodiments provide methods, systems, apparatuses, computer program products and/or the like for reducing diffractive orders arising from metasurface optics. In various embodiments, reducing diffractive orders is achieved by intentional apodization of emergent superstructures and/or intentional amplitude apodization of metasurface apertures. For example, various embodiments provide methods for designing and/or fabricating metasurfaces using a metastructure library that includes parameters defining a plurality of metastructures indexed by respective effective phase delays imparted to light that interacts with the corresponding metastructures. For at least one effective phase delay, the metastructure library comprises parameters that define at least two metastructures that differ in at least one of size or shape and that are indexed by the same effective phase delay.

Abstract: A window component of a controlled environment chamber is provided. The window component includes a window plate; a first array of coupling elements disposed on a first surface of the window plate; a second array of coupling elements disposed on a second surface of the window plate; and a plurality of waveguides formed in a volume of the window plate between the first and second surfaces. A respective waveguide of the plurality of waveguides optically connects a respective first coupling element of the first array of coupling elements to a respective coupling element of the second array of coupling elements.

Abstract: A controlled environment chamber is provided. The controlled environment chamber includes a chamber housing and a window component that is secured to the chamber housing. The window component includes a window plate having a first surface that faces away from an interior of the controlled environment chamber and a second surface that faces toward the interior of the controlled environment chamber. The window plate comprises at least one signal manipulation element.

Abstract: An optical system includes an optical mode filter comprising a metasurface optical element. The metasurface optical element is configured to, in response to an optical beam being incident thereon, emit a selected mode beam with first propagation characteristics and one or more unselected mode beams with respective second propagation characteristic. The first propagation characteristics differ from the respective second propagation characteristics such that a majority of the optical power of the selected mode beam is caused to be incident on at least one of a downstream optical element or a target location and a majority of the optical power of the one or more unselected mode beams is caused to be not incident on the at least one of the downstream optical element or the target location.

Abstract: An optical bench system is provided. The optical bench system includes an array of beam-customized optical components, wherein the array of beam-customized optical components comprises a plurality of beam-customized optical components; and a relay component. Each beam-customized optical component of the plurality of beam-customized optical components is configured to control optical properties of a respective optical beam of a plurality of optical beams to provide a plurality of property-controlled optical beams. The relay component is configured to relay the plurality of property-controlled optical beams to respective target locations of an array of target locations.

Abstract: A composite confinement apparatus assembly is provided. The composite confinement apparatus assembly includes a quantum object confinement apparatus and a photonic platform. The confinement apparatus includes one or more electrical components and is fabricated on a confinement apparatus substrate. The photonic platform includes one or more photonic components that are hosted by a photonic platform substrate. The photonic platform substrate is mechanically coupled to the confinement apparatus substrate to form the composite confinement apparatus assembly.

Abstract: A method for designing a metasurface is provided. The method may include selecting a first metamaterial structure of a plurality of metamaterial structures of the metasurface; generating a forward light propagation model for the first metamaterial structure; generating a reciprocal light propagation model for the first metamaterial structure using a light manipulation function for the metasurface; determining a first electromagnetic response difference between the forward light propagation model and the reciprocal light propagation model; and determining a first property range of the first metamaterial structure such that the first electromagnetic response difference is optimized.

Abstract: An apparatus for cutting brittle material comprises an aspheric focusing lens, an aperture, and a laser-source generating a beam of pulsed laser-radiation. The aspheric lens and the aperture form the beam of pulsed laser-radiation into an elongated focus having a uniform intensity distribution along the optical axis of the aspheric focusing lens. The elongated focus extends through the full thickness of a workpiece made of a brittle material. The workpiece is cut by tracing the optical axis along a cutting line. Each pulse or burst of pulsed laser-radiation creates an extended defect through the full thickness of the workpiece.

Abstract: An apparatus for cutting brittle material comprises an aspheric focusing lens, an aperture, and a laser-source generating a beam of pulsed laser-radiation. The aspheric lens and the aperture form the beam of pulsed laser-radiation into an elongated focus having a uniform intensity distribution along the optical axis of the aspheric focusing lens. The elongated focus extends through the full thickness of a workpiece made of a brittle material. The workpiece is cut by tracing the optical axis along a cutting line. Each pulse or burst of pulsed laser-radiation creates an extended defect through the full thickness of the workpiece.

Abstract: An apparatus for cutting brittle material comprises an aspheric focusing lens, an aperture, and a laser-source generating a beam of pulsed laser-radiation. The aspheric lens and the aperture form the beam of pulsed laser-radiation into an elongated focus having a uniform intensity distribution along the optical axis of the aspheric focusing lens. The elongated focus extends through the full thickness of a workpiece made of a brittle material. The workpiece is cut by tracing the optical axis along a cutting line. Each pulse or burst of pulsed laser-radiation creates an extended defect through the full thickness of the workpiece.

Abstract: Methods of and devices for forming edge chamfers and through holes and slots on a material that is machined using a laser, such as an ultrafast laser. The shaped material has predetermined and highly controllable geometric shape and/or surface morphology. Further, a method of and a device for preventing re-deposition of the particles on a material that is machined using a laser, such as an ultrafast laser. A fluid is used to wash off the particles generated during the laser machining process. The fluid can be in a non-neutral condition, with one or more chemical salts added, or a condition allowing the coagulation of the particles in the fluid, such that the particles can be precipitated to avoid the reattachment to the machined substrate.

Abstract: An apparatus for cutting brittle material comprises an aspheric focusing lens, an aperture, and a laser-source generating a beam of pulsed laser-radiation. The aspheric lens and the aperture form the beam of pulsed laser-radiation into an elongated focus having a uniform intensity distribution along the optical axis of the aspheric focusing lens. The elongated focus extends through the full thickness of a workpiece made of a brittle material. The workpiece is cut by tracing the optical axis along a cutting line. Each pulse or burst of pulsed laser-radiation creates an extended defect through the full thickness of the workpiece.

Abstract: Methods of and devices for forming edge chamfers and through holes and slots on a material that is machined using a laser, such as an ultrafast laser. The shaped material has predetermined and highly controllable geometric shape and/or surface morphology. Further, a method of and a device for preventing re-deposition of the particles on a material that is machined using a laser, such as an ultrafast laser. A fluid is used to wash off the particles generated during the laser machining process. The fluid can be in a non-neutral condition, with one or more chemical salts added, or a condition allowing the coagulation of the particles in the fluid, such that the particles can be precipitated to avoid the reattachment to the machined substrate.

Abstract: The method of and device for cutting brittle materials with tailored edge shape and roughness are disclosed. The methods can include directing one or more tools to a portion of brittle material causing separation of the material into two or more portions, where the as-cut edge has a predetermined and controllable geometric shape and/or surface morphology. The one or more tools can comprise energy (e.g., a femtosecond laser beam or acoustic beam) delivered to the material without making a physical contact.

Abstract: Methods of and devices for forming edge chamfers and through holes and slots on a material that is machined using a laser, such as an ultrafast laser. The shaped material has predetermined and highly controllable geometric shape and/or surface morphology. Further, a method of and a device for preventing re-deposition of the particles on a material that is machined using a laser, such as an ultrafast laser. A fluid is used to wash off the particles generated during the laser machining process. The fluid can be in a non-neutral condition, with one or more chemical salts added, or a condition allowing the coagulation of the particles in the fluid, such that the particles can be precipitated to avoid the reattachment to the machined substrate.

Abstract: The method of and device for cutting brittle materials with tailored edge shape and roughness are disclosed. The methods can include directing one or more tools to a portion of brittle material causing separation of the material into two or more portions, where the as-cut edge has a predetermined and controllable geometric shape and/or surface morphology. The one or more tools can comprise energy (e.g., a femtosecond laser beam or acoustic beam) delivered to the material without making a physical contact.

Abstract: A chirped pulse amplification (CPA) system comprises an optical pulse stretcher and an optical pulse compressor that are mismatched in that the optical pulse compressor includes a bulk optical grating while the optical pulse stretcher does not. High order dispersion compensation is provided by an optical phase mask disposed within the optical pulse compressor.

Abstract: A chirped pulse amplification (CPA) system comprises an optical pulse stretcher and an optical pulse compressor that are mismatched in that the optical pulse compressor includes a bulk optical grating while the optical pulse stretcher does not. High order dispersion compensation is provided by an optical phase mask disposed within the optical pulse compressor.

Abstract: A chirped pulse amplification (CPA) system comprises an optical pulse stretcher and an optical pulse compressor that are mismatched in that the optical pulse compressor includes a bulk optical grating while the optical pulse stretcher does not. High order dispersion compensation is provided by an optical phase mask disposed within the optical pulse compressor.

Abstract: A chirped pulse amplification (CPA) system comprises an optical pulse stretcher and an optical pulse compressor that are mismatched in that the optical pulse compressor includes a bulk optical grating while the optical pulse stretcher does not. High order dispersion compensation is provided by an optical phase mask disposed within the optical pulse compressor.