Abstract: A method of treating zinc sulfide transmissive bodies includes using the same metal layer to treat multiple transmissive bodies, catalyzing the recrystallization of the bodies to remove defects from the bodies and forming multispectral zinc sulfide. The metal layer is brought into contact with one of the transmissive bodies. The transmissive body and the metal layer are then subjected to elevated temperature and pressure. The metal layer may include any of a variety of suitable metals, such as platinum, cobalt, silver, nickel, and/or copper. The metal layer may be a foil that is wrapped around the transmissive body. Alternatively the metal layer may be a rigid metal piece, for example being machined to fit the shape of the transmissive bodies. The reuse of the metal layer to treat multiple transmissive bodies reduces the cost of treating the transmissive bodies.

Abstract: A glaze encapsulated solid-state laser component. The novel laser component includes a core and a cladding of ceramic glaze disposed on a surface of the core. In an illustrative embodiment, the core is fabricated from a laser gain medium and the cladding material is a multi-oxide eutectic ceramic glaze having a refractivity slighter lower than the refractivity of the gain medium, such that the glaze layer forms a step-index refractivity interface cladding that can effectively suppress parasitic oscillations in the core gain medium. The glaze cladding can be applied by coating the core with the glaze and then firing the glaze coated core, or by fabricating pre-formed cladding strips from the ceramic glaze in a first firing cycle, mounting the pre-formed strips to the core, and then fusing the pre-formed strips to the core in a secondary firing cycle.

Abstract: A glaze encapsulated solid-state laser component. The novel laser component includes a core and a cladding of ceramic glaze disposed on a surface of the core. In an illustrative embodiment, the core is fabricated from a laser gain medium and the cladding material is a multi-oxide eutectic ceramic glaze having a refractivity slighter lower than the refractivity of the gain medium, such that the glaze layer forms a step-index refractivity interface cladding that can effectively suppress parasitic oscillations in the core gain medium. The glaze cladding can be applied by coating the core with the glaze and then firing the glaze coated core, or by fabricating pre-formed cladding strips from the ceramic glaze in a first firing cycle, mounting the pre-formed strips to the core, and then fusing the pre-formed strips to the core in a secondary firing cycle.

Abstract: A glaze soldered solid-state laser active medium. The novel laser active medium includes a first section of a first material, a second section of a second material, and a layer of ceramic glaze joining the two sections. The first and second materials may be identical, similar, or dissimilar, and may include crystals or ceramics. The glaze is a multi-oxide eutectic ceramic glaze having a refractivity, light absorption, thermal expansion, and fusion temperature that are compatible with the first material. The sections are joined using a novel glaze soldering process that includes the steps of positioning the sections, applying the ceramic glaze between the sections, and firing the glaze to solder the sections together.

Abstract: A method of treating zinc sulfide transmissive bodies includes using the same metal layer to treat multiple transmissive bodies, catalyzing the recrystallization of the bodies to remove defects from the bodies and forming multispectral zinc sulfide. The metal layer is brought into contact with one of the transmissive bodies. The transmissive body and the metal layer are then subjected to elevated temperature and pressure. The metal layer may include any of a variety of suitable metals, such as platinum, cobalt, silver, nickel, and/or copper. The metal layer may be a foil that is wrapped around the transmissive body. Alternatively the metal layer may be a rigid metal piece, for example being machined to fit the shape of the transmissive bodies. The reuse of the metal layer to treat multiple transmissive bodies reduces the cost of treating the transmissive bodies.

Abstract: A method of treating a transmissive body of zinc sulfide or zinc selenide includes placing a non-platinum metal layer, such as a layer of cobalt, silver, or iron on a surface of the transmissive body, and improving the optical properties of the transmissive body by subjecting the body and the layer to an elevated temperature and elevated pressure. The zinc sulfide or zinc selenide may be chemical vapor deposited material. The non-platinum metal of the layer may be such that a Gibbs free energy of formation of a most stable sulfide (or selenide) of the non-platinum metal is more negative than a Gibbs free energy of formation of a most stable zinc sulfide (or zinc selenide) configuration that is thermodynamically capable of reacting with the non-platinum metal. With this condition the non-platinum metal preferentially chemically bonds with free sulfur (or free selenium) in preference to zinc sulfide (or zinc selenium).