Fiber bragg grating temperature sensor

The invention claimed is: 1. A temperature sensor for sensing changes in temperature up to a predetermined temperature, comprising: a microstructured optical fiber, the microstructured optical fiber including a plurality of longitudinal channels extending along the microstructured optical fiber between a core region and an outer cladding portion of the microstructured optical fiber; and a fiber Bragg grating formed in the microstructured optical fiber by generating a periodic modulation in the refractive index along the core region of the microstructured optical fiber, wherein the periodic modulation in the refractive index along the core region comprises ablated defects, the ablated defects comprising a series of cavities where material has been physically removed from an outer surface portion along the core region of the microstructured optical fiber, wherein the fiber Bragg grating is operable to produce band reflection at a reflection wavelength that varies in accordance with changes in temperature at the core region of the optical fiber. 2. The temperature sensor of claim 1 , wherein the structure of the microstructured optical fiber is configured to facilitate the laser ablating defects along the core region of the microstructured optical fiber. 3. The temperature sensor of claim 2 , wherein one of the plurality of longitudinal channels provides laser access to the core region through only the cladding portion. 4. The temperature sensor of claim 3 , wherein the cross-sectional geometry of the single longitudinal channel is configured to assist the focusing of a laser on the core region for the laser ablating of defects along the core region of the microstructured optical fiber. 5. The temperature sensor of claim 4 , wherein the cross-sectional geometry of the single longitudinal channel includes a substantially planar core region for the ablation of defects. 6. The temperature sensor of claim 4 , wherein the cross-sectional geometry of the single longitudinal channel includes a substantially planar outer surface to the cladding portion. 7. The temperature sensor of claim 4 , wherein the cross-sectional geometry of the single longitudinal channel includes a substantially planar inner surface to the cladding portion. 8. The temperature sensor of claim 2 , wherein the structure of the microstructured optical fiber includes an open longitudinal channel extending along the core region, the open longitudinal channel providing direct laser access to the core region. 9. The temperature sensor of claim 1 , wherein the structure of the microstructured optical fiber is configured to facilitate single mode guidance of electromagnetic radiation along the microstructured optical fiber. 10. The temperature sensor of claim 9 , wherein a selection of the plurality of longitudinal channels extending along the microstructured optical fiber are configured to facilitate single mode guidance by having an average or effective refractive index that satisfies the single mode condition for propagation of electromagnetic radiation along the microstructured optical fiber. 11. The temperature sensor of claim 1 , wherein the microstructured optical fiber is formed of silica material and the sensor is configured for a predetermined temperature of at least 1000° C. 12. The temperature sensor of claim 1 , wherein the microstructured optical fiber is formed of silica material and the sensor is configured for a predetermined temperature of at least 1350° C. 13. The temperature sensor of claim 1 , wherein the microstructured optical fiber is formed of silica material and the sensor is configured for a predetermined temperature of at least 1550° C. 14. The temperature sensor of claim 1 , wherein the microstructured optical fiber is formed of sapphire crystal and the sensor is configured for a predetermined temperature of at least 1600° C. 15. The temperature sensor of claim 1 , wherein the microstructured optical fiber is formed of sapphire crystal and the sensor is configured for a predetermined temperature of at least 2000° C. 16. The temperature sensor according to claim 1 , further comprising a second fiber Bragg grating formed in the microstructured optical fiber by generating a periodic modulation in the refractive index along a second core region of the microstructured optical fiber, the second core region spaced apart from the core region of the fiber Bragg grating, wherein the second fiber Bragg grating is operable to produce band reflection at a second reflection wavelength distinct from the reflection wavelength of the fiber Bragg grating, the second reflection wavelength varying in accordance with changes in temperature at the second core region of the microstructured optical fiber. 17. A multiplexed temperature sensing system comprising: a source of electromagnetic radiation; a temperature sensor as claimed in claim 16 , the temperature sensor interfaced to the source of electromagnetic radiation; a detector for detecting the reflection wavelength of band reflection from the core region where the fiber Bragg grating is located and the second reflection wavelength of band reflection from the second core region where the second fiber Bragg grating is located, the detector interfaced to the temperature sensor; and a data processor for determining the temperature at both the core region and the second core region of the temperature sensor based on the respective shifts of the reflection wavelength and the second reflection wavelength. 18. The multiplexed temperature sensing system of claim 17 , wherein the source of electromagnetic radiation and the detector for detecting the reflection wavelength and the second reflection wavelength are combined. 19. A temperature sensing system comprising: a source of electromagnetic radiation; a temperature sensor as claimed in claim 1 , the temperature sensor interfaced to the source of electromagnetic radiation; a detector for detecting a reflection wavelength of a band reflection from the core region of the temperature sensor where the fiber Bragg grating is located, the detector interfaced to the temperature sensor; and a data processor for determining a temperature at the core region based on the shift of the reflection wavelength. 20. The temperature sensing system of claim 19 , wherein the detector for detecting the reflection wavelength detects a reflected optical signal from the fiber Bragg grating of the temperature sensor. 21. The temperature sensing system of claim 19 , wherein the detector for detecting the reflection wavelength detects a transmitted optical signal from the fiber Bragg grating of the temperature sensor. 22. The temperature sensing system of claim 19 , wherein the source of electromagnetic radiation and the detector for detecting the reflection wavelength are combined.