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666.189.21:666.22 --- 666.22 --- 621.391.6 --- Fiber optics --- Optical communications --- #TELE:TEO --- 621.391 --- 621.39 --- 621.391 General questions of electrical communication engineering. Cybernetics. Information theory. Signal theory --- General questions of electrical communication engineering. Cybernetics. Information theory. Signal theory --- Communications, Optical --- Light communications --- Photonics --- Telecommunication --- Fiberoptics --- Fibre optics --- Fibreoptics --- Optics, Fiber --- Integrated optics --- Optoelectronic devices --- Optical fiber communication --- 621.391.6 Transmission of electric signals by various waves, e.g. ultraviolet, visible light, infra-red --- Transmission of electric signals by various waves, e.g. ultraviolet, visible light, infra-red --- 666.22 Optical glasses --- Optical glasses --- 666.189.21:666.22 Glass fibres and their products. Textile glass-:-Optical glasses --- Glass fibres and their products. Textile glass-:-Optical glasses --- Optical fiber communication. --- Optische vezel telecommunicatie. --- Fiber-optic communication --- Fiber optic telecommunication --- Fiber optics. --- Optical communications.
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Light emitting diodes --- Light emitting diodes. --- 681.7.03 --- #TWER:WTCM --- opto-elektronica --- LED --- isolatoren --- fotodiode --- displays --- 621.3.049.77 --- LED's --- display --- elektronica --- fotometrie --- led --- led display --- led-dokalamp --- led-technologie --- optica --- opto-isolator --- radiometer --- LEDs (Light emitting diodes) --- Diodes, Semiconductor --- Electroluminescent devices --- LED lamps --- Light-emitting electrochemical cells --- Materials for the manufacture of optical apparatus. Optical glasses and other materials --- Opto-elektronica --- Opto-elektronica. --- 681.7.03 Materials for the manufacture of optical apparatus. Optical glasses and other materials --- Diodes électroluminescentes --- TELEVISION --- ELECTRONIC EQUIPMENT --- optical properties electroluminescence semiconductors diodes --- Monograph --- Television. --- Radio vision --- TV --- Artificial satellites in telecommunication --- Electronic systems --- Optoelectronic devices --- Telecommunication --- Astronautics --- Optical communication systems
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Since its first observation in 1850, ion-exchange (IEx) has become a fundamental process in many applications involving water treatment, catalysis, chromatography, and the food and pharmaceutical industries. Starting from the early 1900s, another relevant application of IEx has been in the glass industry, with the surface tempering of glass produced by a K+–Na+ ion exchange. Nowadays, photonics has greatly exploited IEx technology: graded-index microlenses, graded-index fibers and integrated optical waveguides and devices are examples of achievements made possible by the IEx process. Moreover, ion-exchange is possible in ferroelectric crystals, too, and has been fundamental for the development of many linear and nonlinear integrated optical devices in lithium niobate and tantalate.This volume collects articles published in the corresponding Special Issue of the Applied Sciences journal. Four review articles, written by internationally renowned experts in this field, provide complementary overviews of the history, fundamental aspects, designs and fabrications of devices, and technological achievements. Three articles describe original research in the fields of diffraction grating, photo-thermo-refractive glasses, and Yb-doped lithium niobate. This volume constitutes a valuable and updated reference for all students and researchers wishing to improve their knowledge and/or make use of ion-exchange technology and its applications.
Research & information: general --- thermal diffusion --- active waveguide devices --- laser active materials --- ion-exchange --- phase gratings --- diffractive optics --- ion exchange --- silver --- photo-thermo-refractive glass --- silver nanoparticles --- silver molecular clusters --- silver bromide nanocrystals --- integrated photonics --- glass photonics --- optical sensors --- waveguides --- lasers --- optical glasses --- glass strengthening --- noble metal nanoparticles --- rare earths --- luminescence enhancement --- SERS --- flexible photonics --- whispering gallery mode microresonators --- photovoltaic cell --- ion exchange in glass --- ion diffusion --- glass waveguides --- glass poling --- metal nanoparticles --- ion-exchanged glass --- active optical waveguides --- quantum integrated optics --- thermal diffusion --- active waveguide devices --- laser active materials --- ion-exchange --- phase gratings --- diffractive optics --- ion exchange --- silver --- photo-thermo-refractive glass --- silver nanoparticles --- silver molecular clusters --- silver bromide nanocrystals --- integrated photonics --- glass photonics --- optical sensors --- waveguides --- lasers --- optical glasses --- glass strengthening --- noble metal nanoparticles --- rare earths --- luminescence enhancement --- SERS --- flexible photonics --- whispering gallery mode microresonators --- photovoltaic cell --- ion exchange in glass --- ion diffusion --- glass waveguides --- glass poling --- metal nanoparticles --- ion-exchanged glass --- active optical waveguides --- quantum integrated optics
Choose an application
Since its first observation in 1850, ion-exchange (IEx) has become a fundamental process in many applications involving water treatment, catalysis, chromatography, and the food and pharmaceutical industries. Starting from the early 1900s, another relevant application of IEx has been in the glass industry, with the surface tempering of glass produced by a K+–Na+ ion exchange. Nowadays, photonics has greatly exploited IEx technology: graded-index microlenses, graded-index fibers and integrated optical waveguides and devices are examples of achievements made possible by the IEx process. Moreover, ion-exchange is possible in ferroelectric crystals, too, and has been fundamental for the development of many linear and nonlinear integrated optical devices in lithium niobate and tantalate.This volume collects articles published in the corresponding Special Issue of the Applied Sciences journal. Four review articles, written by internationally renowned experts in this field, provide complementary overviews of the history, fundamental aspects, designs and fabrications of devices, and technological achievements. Three articles describe original research in the fields of diffraction grating, photo-thermo-refractive glasses, and Yb-doped lithium niobate. This volume constitutes a valuable and updated reference for all students and researchers wishing to improve their knowledge and/or make use of ion-exchange technology and its applications.
Research & information: general --- thermal diffusion --- active waveguide devices --- laser active materials --- ion-exchange --- phase gratings --- diffractive optics --- ion exchange --- silver --- photo-thermo-refractive glass --- silver nanoparticles --- silver molecular clusters --- silver bromide nanocrystals --- integrated photonics --- glass photonics --- optical sensors --- waveguides --- lasers --- optical glasses --- glass strengthening --- noble metal nanoparticles --- rare earths --- luminescence enhancement --- SERS --- flexible photonics --- whispering gallery mode microresonators --- photovoltaic cell --- ion exchange in glass --- ion diffusion --- glass waveguides --- glass poling --- metal nanoparticles --- ion-exchanged glass --- active optical waveguides --- quantum integrated optics
Choose an application
Since its first observation in 1850, ion-exchange (IEx) has become a fundamental process in many applications involving water treatment, catalysis, chromatography, and the food and pharmaceutical industries. Starting from the early 1900s, another relevant application of IEx has been in the glass industry, with the surface tempering of glass produced by a K+–Na+ ion exchange. Nowadays, photonics has greatly exploited IEx technology: graded-index microlenses, graded-index fibers and integrated optical waveguides and devices are examples of achievements made possible by the IEx process. Moreover, ion-exchange is possible in ferroelectric crystals, too, and has been fundamental for the development of many linear and nonlinear integrated optical devices in lithium niobate and tantalate.This volume collects articles published in the corresponding Special Issue of the Applied Sciences journal. Four review articles, written by internationally renowned experts in this field, provide complementary overviews of the history, fundamental aspects, designs and fabrications of devices, and technological achievements. Three articles describe original research in the fields of diffraction grating, photo-thermo-refractive glasses, and Yb-doped lithium niobate. This volume constitutes a valuable and updated reference for all students and researchers wishing to improve their knowledge and/or make use of ion-exchange technology and its applications.
thermal diffusion --- active waveguide devices --- laser active materials --- ion-exchange --- phase gratings --- diffractive optics --- ion exchange --- silver --- photo-thermo-refractive glass --- silver nanoparticles --- silver molecular clusters --- silver bromide nanocrystals --- integrated photonics --- glass photonics --- optical sensors --- waveguides --- lasers --- optical glasses --- glass strengthening --- noble metal nanoparticles --- rare earths --- luminescence enhancement --- SERS --- flexible photonics --- whispering gallery mode microresonators --- photovoltaic cell --- ion exchange in glass --- ion diffusion --- glass waveguides --- glass poling --- metal nanoparticles --- ion-exchanged glass --- active optical waveguides --- quantum integrated optics
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