The present application provides a process of fabrication of erbium and ytterbium-co-doped multielements silica glass based cladding-pumped fiber for use as a highly efficient high power optical amplifier.

The present application provides a process of fabrication of erbium and ytterbium-co-doped multielements silica glass based cladding-pumped fiber for use as a highly efficient high power optical amplifier.

In a unit gravity environment, a glass preform is encased in a material to generate an encased glass preform. The material remains solid at the glass preform's crystal melting temperature and is inert with respect to the glass preform. The encased glass preform is placed in a microgravity environment and heated to a temperature above the crystal melting temperature until the glass preform melts and is free of crystals, wherein a crystallite-free glass preform is encased within the material. The crystallite-free glass preform is then cooled in the microgravity environment to generate a solid crystallite-free glass preform encased within the material. While still in the microgravity environment, the material encasing the solid crystallite-free glass preform is removed in the microgravity environment and the solid crystallite-free glass preform is polished. A glass optical fiber is then drawn from the solid crystallite-free glass preform in the microgravity environment.

In a unit gravity environment, a glass preform is encased in a material to generate an encased glass preform. The material remains solid at the glass preform's crystal melting temperature and is inert with respect to the glass preform. The encased glass preform is placed in a microgravity environment and heated to a temperature above the crystal melting temperature until the glass preform melts and is free of crystals, wherein a crystallite-free glass preform is encased within the material. The crystallite-free glass preform is then cooled in the microgravity environment to generate a solid crystallite-free glass preform encased within the material. While still in the microgravity environment, the material encasing the solid crystallite-free glass preform is removed in the microgravity environment and the solid crystallite-free glass preform is polished. A glass optical fiber is then drawn from the solid crystallite-free glass preform in the microgravity environment.

A method is provided for forming a melt-resistant glass fiber product, by applying an insulating material to a glass fiber product comprised of filiform glass fibers so as to substantially coat each of the filiform glass fibers therewith, such that the coated filiform glass fibers render the glass fiber product resistant to heat. In one aspect, such a method comprises forming a wetted mixture including filiform glass fibers and insulating material comprising a fire-retarding solution, wherein the wetted mixture has a solids content of the fire-retarding solution substantially uniformly and thoroughly dispersed therethrough. An associated apparatus is also provided.

A method is provided for forming a melt-resistant glass fiber product, by applying an insulating material to a glass fiber product comprised of filiform glass fibers so as to substantially coat each of the filiform glass fibers therewith, such that the coated filiform glass fibers render the glass fiber product resistant to heat. In one aspect, such a method comprises forming a wetted mixture including filiform glass fibers and insulating material comprising a fire-retarding solution, wherein the wetted mixture has a solids content of the fire-retarding solution substantially uniformly and thoroughly dispersed therethrough. An associated apparatus is also provided.

Provided is a method for manufacturing an optical connector. The optical connector includes: an optical fiber including a glass fiber and a resin coating; and a ferrule including a through hole. The method for manufacturing includes: coating an inner wall of the through hole with a thermosetting resin; inserting the glass fiber exposed from the resin coating into the through hole; adjusting a mutual positional relationship between the optical fiber and the ferrule so that a distance between end surfaces of a tip of the glass fiber and a tip of the ferrule is equal to or less than 1 mm; rotationally aligning the glass fiber with respect to the ferrule; curing the thermosetting resin; and polishing the tip of the glass fiber and the tip of the ferrule.

Provided is a method for manufacturing an optical connector. The optical connector includes: an optical fiber including a glass fiber and a resin coating; and a ferrule including a through hole. The method for manufacturing includes: coating an inner wall of the through hole with a thermosetting resin; inserting the glass fiber exposed from the resin coating into the through hole; adjusting a mutual positional relationship between the optical fiber and the ferrule so that a distance between end surfaces of a tip of the glass fiber and a tip of the ferrule is equal to or less than 1 mm; rotationally aligning the glass fiber with respect to the ferrule; curing the thermosetting resin; and polishing the tip of the glass fiber and the tip of the ferrule.

A method is provided for forming a melt-resistant glass fiber product, by applying an insulating material to a glass fiber product comprised of filiform glass fibers so as to substantially coat each of the filiform glass fibers therewith, such that the coated filiform glass fibers render the glass fiber product resistant to heat. In one aspect, such a method comprises forming a wetted mixture including filiform glass fibers and insulating material comprising a fire-retarding solution, wherein the wetted mixture has a solids content of the fire-retarding solution substantially uniformly and thoroughly dispersed therethrough. An associated apparatus is also provided.

A method is provided for forming a melt-resistant glass fiber product, by applying an insulating material to a glass fiber product comprised of filiform glass fibers so as to substantially coat each of the filiform glass fibers therewith, such that the coated filiform glass fibers render the glass fiber product resistant to heat. In one aspect, such a method comprises forming a wetted mixture including filiform glass fibers and insulating material comprising a fire-retarding solution, wherein the wetted mixture has a solids content of the fire-retarding solution substantially uniformly and thoroughly dispersed therethrough. An associated apparatus is also provided.