Opto-mechanical Response Of A Suspended-slab-core Optical Fiber

In this paper we report the numerical evaluation of the opto-mechanical response of a microstructured optical fiber design when submitted to hydrostatic pressure. The fiber was built in silica and is composed of two large holes surrounding a wide thin flat region (suspended-slab-core) that is able to support optical propagating modes. A full-vector finite element program was used to the stress-optical analysis. The opto-mechanical sensitivity of such fiber was evaluated under two schemes of applied hydrostatic pressure. © American Institute of Physics.1055141144Bjarklev, A., Broeng, J., Bjarklev, A.S., (2003) Photonic Crystal Fibres, , Boston, Kluwer Academic PublishersJoly, N.Y., Birks, T.A., Yulin, A., Knight, J.C., St. Russel, P.J., (2005) Optics Letters, 30 (18), pp. 2469-2471Szpulak, M., Martynkien, T., Urbanczyk, W., (2004) Applied Optics, 43 (24), pp. 4739-4744Schreiber, T., Schultz, O., Schmidt, O., Röser, F., Limpert, J., Tünnermann, A., (2005) Optics Express, 13 (10), pp. 3637-3646MacPherson, W.N., Rigg, E.J., Jones, J.D.C., Kumar, V.V.R.K., Knight, J.C., St, P., Russel, J., (2005) IEEE J. Lightwave Technol, 23 (3), pp. 1227-123

Hybrid Photonic Crystal Fiber Sensing Of High Hydrostatic Pressure

The opto-mechanical response of Hybrid Photonic Crystal Fiber (HPCF) with Ge-doped inclusions is numerically modeled for high hydrostatic pressure sensing purpose. A typical photonic crystal fiber (PCF) consists of a silica solidcore and a cladding with a hexagonal lattice of air-holes. The HPCF is similar to the regular PCF, but a horizontal line of air-holes is substituted by solid high index rods of Ge-doped silica. The optical guidance in HPCFs is supported combining two physical effects: the modified total internal reflection and the photonic bandgap. In such fibers, the Gedoped inclusions induce residual birefringence. In our analysis, we evaluate the susceptibility of the phase modal birefringence and group birefringence to hydrostatic pressure. The analyses were performed at a photonic bandgap with central wavelength near to 1350 nm. The polarimetric pressure sensitivity is about 10 rad/MPa x m at λ = 1175 nm. © 2011 Copyright Society of Photo-Optical Instrumentation Engineers (SPIE).7753Oz Optics,Simbol Test Systems, Inc.,FISO Technologies, Inc.,CMC Microsystems Corporation,Innovative Economy: National Strategic Reference FrameworkCerqueira, A.S., Hybrid photonic crystal fiber (2006) Opt. Express, 14 (2), pp. 926-931Cerqueira, A.S., Recent progress and novel applications of photonic crystal fibers (2010) Rep. Prog. Phys., 73, p. 023301Cerqueira, A.S., Birefringence properties of hybrid photonic crystal fibers (2009) Proceedings of Microwave and Optoelectronics Conference (IMOC 2009), pp. 804-806. , Belem, Brazil, 03-06, NovemberFranco, M.A.R., Thermal tunability of photonic bandgaps in photonic crystal fibers selectively filled with nematic liquid crystal Proceedings of 2nd Workshop on Specialty Optical Fibers and Their Applications (WSOF-2), Oaxaca, Mexico, 13-15, October, (2010)Fleming, J.W., Dispersion in GeO2 -SiO2 glasses (1984) Appl. Opt., 23 (24), pp. 4486-4493Martynkien, T., Highly birefringent microstructured fibers with enhanced sensitivity to hydrostatic pressure (2010) Opt. Express, 18 (14), pp. 15113-15121Kühn, B., Schadrack, R., Thermal expansion of synthetic fused silica as a function of OH content and fictive temperature (2009) J. Non-Cryst. Solids, 355, pp. 323-326Gupta, D., Kumar, A., Thyagarajan, K., Polarization mode dispersion in single mode optical fibers due to core-ellipticity (2006) Opt. Commun., 263, pp. 36-41Koshiba, M., (1992) Optical Waveguide Theory by the Finite Element Method, pp. 133-160. , KTK Scientific Publishers and Kluwer Academic Publishers, TokyoUrbanczyk, W., Martynkien, T., Bock, W.J., Dispersion effects in elliptical-core highly birefringent fibers (2001) Appl. Opt., 40 (12), pp. 1911-1920Olszewski, J., Birefringence analysis in photonic crystal fibers with germanium-doped core (2009) J. Opt. A: Pure Appl. Opt., 11, pp. 1-10Martynkien, T., Urbanczyk, W., Modeling of spectral characteristics of Corning PMF-38 highly birefringent fiber (2002) Optik, 113 (1), pp. 25-30Hlubina, P., Broad spectral range measurements and modelling of birefringence dispersion in two-mode elliptical-core fibres (2010) J. Opt., 12, pp. 1-8Martynkien, T., Birefringence in microstructure fiber with elliptical GeO2 highly doped inclusion in the core (2008) Opt. Lett., 33 (23), pp. 2764-2766Verbandt, Y., Polarimetric Optical Fiber Sensors: Aspects of Sensitivity and Practical Implementation (1997) Opt. Rev., 4 (1 A), pp. 75-79Lagakos, N., Bucaro, J.A., Hughes, R., Acoustic sensitivity predictions of single-mode optical fibers using Brillouin scattering (1980) Appl. Opt., 19 (21), pp. 3668-3670Chiang, K.S., Sceats, Wong, D., Ultraviolet photolytic-induced changes in optical fibers: The thermal expansion coefficient (1993) Opt. Lett., 18 (12), pp. 965-96

Multiphysics Analysis Of An All-photonic Crystal Fiber Device

A multiphysics analysis of an all-fiber device based on photonic crystal fiber is reported. The device is a solid-core high-birefringent photonic crystal fiber with two integrated electrodes at the cladding region. A finite clement code was used to perform an electro-thermo-mechanical-opto coupled analysis. The device operates applying an electrical current on the integrated electrodes that causes heating by Joule effect and, consequently, its thermal expansion which squeezes the fiber microstructure. The results demonstrate the possibility of actively tuning the modal birefringence with electrical current. ©2009IEEE.800803Chesini, G., Cristiano, M., Cordeiro, B., Christiano, J., De Matos, S., Fokine, M., Isabel, C., Knight, J.C., All-fiber devices based on photonic crystal fibers with integrated electrodes (2009) Optics Express, 17 (3), pp. 1660-1665. , FebruaryFokine, M., Nilsson, L.E., Claesson, A., Berlemont, D., Kjellberg, L., Krummenacher, L., Margulis, W., Integrated fiber Mach-Zehnder interferometer for electro-optic switching (2002) Opt. Lett., 27, pp. 1643-1645Lienhard IV, J.H., Lienhard V, J.H., (2006) A Heat Transfer Textbook, , 3rd ed. Cambridge: Massachutts, Phlogiston Pres