Optical fiber for temperature sensing, and system and method for measuring temperature

The invention claimed is: 1 . An optical fiber for temperature sensing, the optical fiber comprising: a core surrounded by a cladding, the core comprising an alkaline-earth fluorosilicate glass including defects, and the cladding comprising a silica glass, wherein, when pumped with infrared light, the defects emit green light at an intensity dependent on a temperature of the optical fiber. 2 . The optical fiber of claim 1 , wherein the defects include silica defects selected from the group consisting of non-bridging oxygen hole centers, E centers, peroxy radicals, oxygen deficient network linkages, oxygen-excess peroxy linkages, self-trapped excitons, silanones, dioxasilyrane groups, and diamagnetic silylene oxygen divacancies. 3 . The optical fiber of claim 1 , wherein a number density or concentration of the defects in the alkaline-earth fluorosilicate glass is at least about 1×10 21 m 3 . 4 . The optical fiber of claim 1 , wherein the alkaline-earth fluorosilicate glass consists of: an alkaline earth metal selected from the group consisting of Ba, Ca, Mg, and Sr; fluorine; silicon; oxygen; and incidental impurities. 5 . The optical fiber of claim 4 , wherein a composition of the alkaline earth fluorosilicate glass at a center of the core consists of: the alkaline-earth metal at a concentration in a range from about 1-10 at. %; the fluorine at a concentration in a range from about 1-10 at. %; the oxygen at a concentration in a range from about 60-70 at. %; and the incidental impurities at a concentration no greater than about 1000 ppm, wherein the silicon accounts for a balance of the composition. 6 . The optical fiber of claim 4 , wherein the alkaline earth fluorosilicate glass exhibits a composition gradient between a center of the core and a core-cladding interface, wherein, in a direction away from the center of the core, a concentration of the alkaline earth metal and a concentration of the fluorine decrease, and a concentration of the silicon and a concentration of the oxygen increase. 7 . The optical fiber of claim 1 , wherein the alkaline-earth fluorosilicate glass does not include a rare earth dopant, wherein the alkaline-earth fluorosilicate glass does not include quantum dots, nanocrystals, or microcrystals, and/or wherein the alkaline-earth fluorosilicate glass does not include alumina (Al 2 O 3 ). 8 . The optical fiber of claim 1 , wherein the defects are distributed along a length of the optical fiber. 9 . The optical fiber of claim 1 , wherein the intensity of the green light is at least about 10 −10 W/m 2 . 10 . A system for measuring temperature, the system comprising: the optical fiber of claim 1 ; a light source configured to supply infrared light to the optical fiber; a light sensor configured to detect optical light emitted from the optical fiber; signal processing software configured to determine an intensity value of the detected optical light; and calibration data for converting the intensity value to a temperature value. 11 . A method of measuring temperature, the method comprising: positioning an optical fiber in contact with an object or in an environment having a temperature to be determined, the optical fiber comprising a core surrounded by a cladding, the core comprising an alkaline-earth fluorosilicate glass including defects, and the cladding comprising a silica glass; supplying infrared light to the optical fiber, thereby electronically exciting the defects; detecting green light emitted from the defects as a consequence of the electronic excitation; and determining an intensity value of the green light; and using calibration data to convert the intensity value of the green light to a temperature value for the optical fiber, thereby determining the temperature of the object or the environment. 12 . The method of claim 11 , wherein the intensity value of the green light increases as the temperature decreases. 13 . The method of claim 11 , wherein the temperature is in a range from about −269° C. to about 200° C. 14 . The method of claim 11 , wherein the intensity value is one of a plurality of intensity values determined along the length of the optical fiber, and wherein the calibration data are used to convert the plurality of intensity values to a plurality of temperature values along the length of the optical fiber, thereby obtaining a distributed measurement of the temperature of the object or the environment. 15 . The method of claim 11 , wherein an emission spectrum of the green light has an asymmetric Gaussian shape. 16 . The method of claim 11 , wherein an emission spectrum of the green light has a Pekarian shape. 17 . The method of claim 11 , wherein the infrared light has a wavelength in a range from about 976 nm to about 1070 nm. 18 . The method of claim 11 , wherein the wavelength of the peak intensity value is independent of temperature. 19 . The method of claim 11 , wherein the green light is detected using a light sensor selected from the group consisting of: a complementary metal-oxide semiconductor (CMOS) sensor and a charge coupled device (CCD) sensor. 20 . A method of making an optical fiber, the method comprising: inserting a powder consisting of an alkaline earth metal and fluorine into a silica tube; after inserting the powder, heating the silica tube to a temperature sufficient to induce melting of the powder; drawing the silica tube to form a drawn cylindrical body including a molten core region in which diffusion and/or chemical reactions occur, leading to defect formation; and cooling the drawn cylindrical body to solidify the core, thereby forming an optical fiber, the core comprising an alkaline-earth fluorosilicate glass including defects, and the cladding comprising a silica glass.