A process for optically sorting a plurality of particles includes: providing a particle receiver; producing particles; receiving the particles by the particle receiver; receiving a light by the particle receiver; producing a standing wave optical interference pattern in an optical interference site of the particle receiver from the light; subjecting the particles to an optical gradient force from the standing wave optical interference pattern; deflecting the particles into a plurality of deflected paths to form the sorted particles from the particles; and propagating the sorted particles from the optical interference site through the deflected paths to optically sort the particles

An etalon may include a plurality of reflectors, wherein at least one reflector, of the plurality of reflectors, is partially reflecting of light in a frequency range and each other reflector, of the plurality of reflectors is either partially or fully reflecting of light in the frequency range, and wherein the plurality of reflectors comprises at least three reflectors arranged to define a volume of a resonant optical cavity.

A delay mirror 1 includes a base 2, and an optical multilayer film 4 formed on a surface R of the base 2. The value of a group delay in a first wavelength band according to the optical multilayer film 4 is different from the value of the group delay in the second wavelength band according to the optical multilayer film 4, and the value of a group delay dispersion in the first wavelength band according to the optical multilayer film 4 and the value of the group delay dispersion in the second wavelength band according to the optical multilayer film 4 are each not less than −100 fs.sup.2 and not greater than 100 fs.sup.2. Further, the delay mirror system includes a delay mirror movement mechanism which moves the delay mirror 1 such that the number of times of reflection is changed.

An extended optical pulse stretcher is provided that combines confocal pulse stretchers in combination to produce, for example, 4 reflections, 4 reflections, 12 reflections, and 12 reflections per optical circuit configuration. The inclusion of the combination of different mirror separations and delay path lengths can result in very long pulse stretching, long optical delays, and minimal efficiency losses. Also, in the extended optical pulse stretcher, at least a beam splitter can be positioned relative to the center of curvature of the mirrors to “flatten” each of the circuits to enable the beam to propagate in the same plane (e.g., parallel to the floor). Also, the curvatures and sizes of the individual mirrors can be designed to position the beam splitter closer to one of the banks of mirrors to allow the optical pulse stretchers to properly fit in an allocated location in a laser system.

A sensor device includes: a light-emitting section that outputs light to a first mirror or a second mirror, the second mirror facing the first mirror and being configured to change an orientation with respect to the first mirror; and a light-receiving section that receives reflection light, reflected from the first mirror and the second mirror, of the light outputted from the light-emitting section.

An optical device includes: a base including a mounting surface; and an optical component including an optical element part, a support part including a first adhered surface bonded to the mounting surface via a photocurable first adhesive, the support part being configured to support the optical element part, and an optical opening part provided adjacent to the first adhered surface, the optical opening part allowing light for curing the first adhesive to pass through.

An optical device for a head-mounted display device includes a first partial reflector and a second partial reflector positioned relative to the first partial reflector so that the second partial reflector receives first light transmitted through the first partial reflector and reflects at least a portion of the first light toward the first partial reflector as second light. At least a portion of the second light is reflected by the first partial reflector as third light, and at least a portion of the third light is transmitted through the second partial reflector. At least one of the first partial reflector or the second partial reflector includes a reflective holographic element.

A recycling optical cavity is defined at least by first and second optical films and is configured to receive a test material therein. The test material is configured to emit at least a second light having a second wavelength when irradiated with a first light having a first wavelength. For at least one of s- and p-polarized incident lights incident in an incident plane, and at the first and second wavelengths: at a first incident angle, the first optical film has respective optical transmittances T11(θ1) and T12(θ1), and the second optical film has respective optical transmittances T21(θ1) and T22(θ1), wherein T11(θ1)>T12(θ1), T21(θ1), T22(θ1); and at a second incident angle, the first optical film has respective optical transmittances T11(θ2) and T12(θ2), and the second optical film has respective optical transmittances T21(θ2) and T22(θ2), wherein T21(θ2)>T11(θ2), T12(θ2), T22(θ2).

In various implementations, a sample cell for optical analysis can include a housing configured to confine a sample to be analyzed. The cell can include at least one planar reflector and at least one concave reflector. The at least one planar reflector can be disposed in the housing to receive light from a light source. The at least one concave reflector can be disposed in the housing with respect to the at least one planar reflector to receive light reflected from the at least one planar reflector and to reflect at least of portion of the light back to the at least one planar reflector. The at least one planar reflector can be configured to reflect at least a portion of the light away from said at least one planar reflector to be analyzed.

Provided is an ATR prism, including a material having an internal transmittance of 90% or higher at a wavelength falling within a wavelength range of from 8 μm to 10 μm, when the material has a thickness of 2 mm. The ATR prism includes: a first surface including a first totally reflecting surface; a second surface including a second totally reflecting surface; and a recessed portion formed in one of the first surface or the second surface.