A laser glass doped with high concentration of mid-infrared fluoroindate and a preparation method thereof are provided in the present application, belonging to the technical field of luminescent glass. The laser glass doped with high concentration of mid-infrared fluoroindate includes the raw materials in parts by mole percentage: 27-38 parts of InF.sub.3, 13 parts of ZnF.sub.2, 10 parts of GdF.sub.3, 19 parts of BaF.sub.2, 5 parts of CaF.sub.2, 10 parts of SrF.sub.2, 5-15 parts of Al(PO.sub.3).sub.3 and 1-11 parts of ErF.sub.3.

Disclosed herein are seals for liquid-tight bonding of an optical window comprising a BiIn alloy. Also disclosed are optical cells comprising the BiIn alloy seals to provide a liquid-tight seal between a cell housing and a drilled optical window.

Disclosed herein are seals for liquid-tight bonding of an optical window comprising a BiIn alloy. Also disclosed are optical cells comprising the BiIn alloy seals to provide a liquid-tight seal between a cell housing and a drilled optical window.

A single-band upconversion luminescent material includes an amorphous ceramic host; and lanthanide ions doped into the ceramic host.

Disclosed herein are seals for liquid-tight bonding of an optical window comprising a BiIn alloy. Also disclosed are optical cells comprising the BiIn alloy seals to provide a liquid-tight seal between a cell housing and a drilled optical window.

Aspects of the embodiments include an optical fiber formed in a low gravity environment. The optical fiber can be used in airframe applications for missile defense, oil-field applications for down-well laser applications, optical communications, and other applications. The optical fiber can include a fluoride composition, such ZrF4-BaF2-LaF3-AlF3-NaF (ZBLAN), and can be characterized by an insertion loss in a range from 13 dB/1000 km to 120 dB/1000 km. The optical fiber can deliver optical energy with low insertion loss at the desired power and wavelength for the various applications.

A bonded ceramic component which is resistant to reactive halogen-containing plasmas, said component comprising ceramic portions which are bonded together by a bonding material which includes an oxyfluoride glass-ceramic-comprising transition area between interfaces of the ceramic portions, where the transition area includes form at least 0.1 volume % amorphous phase up to about 50 volume % amorphous phase.

A bonded ceramic component which is resistant to reactive halogen-containing plasmas, said component comprising ceramic portions which are bonded together by a bonding material which includes an oxyfluoride glass-ceramic-comprising transition area between interfaces of the ceramic portions, where the transition area includes from at least 0.1 volume % amorphous phase up to about 50 volume % amorphous phase.

An optical fiber with a double-clad fluoride with low loss and high pump absorption efficiency, and its preparation method are provided. The gain optical fiber with the double-clad fluoride includes a fiber core, a D-shaped inner cladding, an outer cladding, and a polymer coating, wherein the fiber core, the inner cladding, and the outer cladding are all fluoride glass materials, and the polymer coating is a fluorinated ethylene propylene copolymer. The fiber core and inner cladding structure are prepared by a suction injection method, and the inner cladding is polished into a D-shaped structure, and the outer cladding is prepared by a core insertion casting method to form an optical fiber preform with D-shaped double-clad fluoride and draw an optical fiber.

Embodiments are directed to systems and methods for material processing in a low gravity environment, and an optical fiber formed in a low gravity environment. In at least one embodiment, a glass part (e.g., a preform, optical fiber, optical waveguide, etc.) is produced by printing one or more glass materials using nozzles fed by heated apparatuses (e.g., syringes or crucibles).