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Conference CommitteeConference Chair Session Chairs
PrefaceTwo distinctly different types of guiding structures are used to make glass waveguide devices: optical fibers and integrated optical waveguides. There has been remarkable progress in optical fiber devices. Optical fibers have been used to study and demonstrate a number of important phenomena such as optical amplification, soliton propagation, and pulse break-up. All-fiber devices have been produced using readily available optical fibers. Glass integrated optics was rather slow starting, but outstanding progress has been achieved during the past decade or so. High performance integrated optical devices and circuits have been fabricated.1-3 Different techniques are used to make glass integrated optical devices. Ion-exchange is the most popular. This technique is simple and can be used to make reproducible and low-cost devices. Recently, a flame hydrolysis technique has attracted attention, probably because the resultant waveguides can be fused to optical fiber, which improves environmental stability of the chip and eliminates back reflection in the fiber-chip interface. Plasma deposition offers the possibility of doping waveguides to achieve nonlinear devices. The sol-gel method is flexible and can be used to make waveguides with different dopants (e.g., rare earths, semiconductors, photosensitive elements). It is also attractive for fabrication of hybrid circuits. Figure 1 depicts a hybrid 1.3 μm/1.55 μm amplifier/splitter.2 Ion implantation also has been employed to make glass waveguides. In addition, we have used Ge implantation to make waveguides. A simple photoresist mask has been used to produce channel waveguides. However, the waveguides had rather high propagation losses. In addition, the fabrication process is very costly and is not suitable for device fabrication. Accurate theoretical tools have been developed to design glass integrated optical devices.4-6 New and complex devices have been proposed, analyzed, and demonstrated. In particular, waveguides with grating have attracted a lot of attention.7,8 Figures 2 and 3 depict two examples of such devices. In Figure 2 we propose a new rare-earth-doped glass waveguide laser. The grating with variable width is used to diffract a symmetric laser beam perpendicular to the waveguide surface. In Figure 3 we suggest a narrow band wavelength division multi/demultiplexer.9 This critical review includes papers, authored by recognized experts, discussing optical fibers and the progress and future potential of glass integrated optical devices. ReferencesS. I. Najafi, Introduction to Glass Integrated Optics, Artech House, Boston
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S. I. Najafi and Seppo Honkanen,
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S. Honkanen, A. Tervonen, and S. I. Najafi,
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in Conf. on Europ. Fiber Optics Communications and Networks,
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P. Auger and S. I. Najafi,
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S. I. Najafi, S. Honkanen, and A. Tervonen,
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S. I. Najafi,
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P. Lefebvre, S. I. Najafi, and M. Kavehrad,
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