Manufacturing and Characterization of Buried Optical Waveguide Stack in Glass Substrate

doi:10.3724/SP.J.1077.2012.11687

Abstract

Abstract: On silicate optical glass substrate, buried optical waveguide stacks were obtained. The stacks were composed of two layers of buried optical channel waveguide at different depth beneath the glass substrate surface, and each layer was manufactured by thermal Ag⁺/Na⁺ ion-exchange and field-assisted ion-diffusion. Microstructure of the optical waveguide chips was observed with optical microscope, and insertion loss of each layer in waveguide stacks is measured. Results show that the buried waveguide stack is composed of two layers of buried waveguide with their core center located at 14 μm and 35 μm, respectively. Beneath the glass surface, core dimension of top layer and bottom layer waveguide are 12 μm×7 μm and 9 μm×8 μm, respectively. Waveguides in both layers are single mode at operating wavelength of 1.55 μm. There is no directional coupling observed between waveguides at different layers. Insertion loss characterization indicates that propagation loss of both layers in the stack is 0.12 dB/cm, and coupling losses with single mode fiber are 0.78 dB/facet and 0.73 dB/facet, for top and bottom layer waveguides, respectively. The analysis suggests that this kind of optical waveguide stack is promising in application of high density integration of glass-based optical chip.

Key words: glass, ion-exchange, waveguide, stack

CLC Number:

TN252

ZHENG Bin, HAO Yin-Lei, LI Yu-Bo, YANG Jian-Yi, JIANG Xiao-Qing, ZHOU Qiang, WANG Ming-Hua. Manufacturing and Characterization of Buried Optical Waveguide Stack in Glass Substrate[J]. Journal of Inorganic Materials, 2012, 27(9): 906-910.

References

[1] Ramaswamy R V. Ion-exchanged glass waveguide: a review. Journal of Lightwave Technology, 1988, 6(6): 984-1002.

[2] Tervonen A, Honkanen S, West B R. Ion-exchanged glass waveguide technology: a review. Optical Engineering, 2011, 50(7): 071107-1-15.

[3] Izawa T, Nakagome H. Optical waveguide formed by electrically induced migration of ions in glass plates. Applied Physics Letters, 1972, 21(12): 584-586.

[4] HAO Yin-Lei. Adaptability of glass properties estimating model for GRIN optic elements. Journal of Inorganic Materials, 2003, 18(2): 295-300.

[5] West B R, Madasamy P, Peyghambarian N, et al. Modeling of ion- exchanged glass waveguide structure. Journal of Non-Crystalline Solids, 2004, 347(1/2/3): 18-26.

[6] HAO Yin-lei, ZHENG Wei-wei, JIANG Shu-hang, et al. Manufacturing and analysis of low-loss ion-exchanged glass-based waveguide. Journal of Inorganic Materials, 2009, 24(5): 1041-1044.

[7] TIAN He-bin, YANG Tian-xin, WANG Yong-qiang, et al. Fabrication and characterization of field-assisted K+-Na+ ion exchanged glass optical waveguides. Journal of Tianjin Institute of Technology, 2002, 18(4): 6-8.

[8] ZHOU Zi-gang, LIU De-sen. Two-step ion-exchange waveguides splitter with low-loss. Chinese Journal of Lasers, 2004, 31(6): 665-668.

[9] Tervonen A, Poyhonen P, Honkanen S, et al. A guided-wave Mach-Zehnder interferometers structure for wavelength multiplexing. IEEE Photonics Technology Letters, 1991, 3(6): 516-518.

[10] HAN Xiu-you, PANG Fu-fei, CHU Feng-hong, et al. Characterization and fabrication of ion-exchanged glass waveguides with mixed melt salt. Journal of Optoelectronics Laser, 2006, 17(9): 1052-1056, 1077.

[11] Delavaux J M P, Granlund S, Mizuhara O, et al. Integrated optics erbium-ytterbium amplifier system in 10-Gb/s fiber transmission experiment. IEEE Photonics Technology Letters, 1997, 9(2): 247-249.

[12] Bastard L, Blaize S, Broquin J E. Glass integrated optics ultranarrow linewidth distributed feedback laser matrix for dense wavelength division multiplexing applications. Optical Engineering, 2003, 42(10): 2800-2804.

[13] Jose G, Sorbello G, Taccheo S, et al. Active waveguide devices by Ag–Na ion exchange on erbium–ytterbium doped phosphate glasses. Journal of Non-Crystalline Solids, 2003, 322(1/2/3): 256-261.

[14] ZHANG Jin-ling, LIU Yong-zhi, ZHANG Xiao-xia. Nd3+-doped phosphate glass waveguide fabricated by ion exchange. Semiconductor Optoelectronics, 2008, 29(4): 544-547.

[15] ZHENG Jie, WANG Peng-fei, XU Mai, et al. Characterization of ion exchange erbium-doped silica glass amplifiers. Acta Optica Sinica, 2003, 23(12): 1418-1423.

[16] ZHAO Shi-long, XU Shi-qing, WANG Bao-ling, et al. Er3+/Yb3+ codoped phosphate glass planar waveguides by Ag+-Li+ ion exchange. Acta Photonica Sinica, 2009, 37(4): 818-821.

[17] Shao G W, Jin G L, Li Q. Gain and noise figure characteristics of an Er3+-Yb3+ doped phosphate glass waveguide amplifier with a bidirectional pump scheme and double-pass configuration. Optical Engineering, 2008, 47(10): 104201.

[18] Noutsios P C, Yip G L, Albert J. Novel vertical directional coupler made by field-assisted ion-exchanged slab waveguides in glass. Electronics Letters, 1992, 28(14): 1340?1342.

[19] Onestas L, Bucci D, Ghibaudo E, et al. Vertically integrated broadband duplexer for erbium-doped waveguide amplifiers made by ion exchange on glass. IEEE Photonics Technology Letters, 2011, 23 (10): 648-650.

[20] Grelin J, Ghibaudo E, Broquin J E. Study of deeply buried waveguides: A way towards 3D integration. Materials Science and engineering B, 2008, 149(2): 185-189.

[21] Fantone S D. Refractive index and spectral model for gra-dient-index materials. Appl. Opt., 1983, 22(3): 432-440.