EUROPIUM: COMPOUNDS, PRODUCTION AND APPLICATIONS -- EUROPIUM: COMPOUNDS, PRODUCTION AND APPLICATIONS -- Library of Congress Cataloging-in-Publication Data -- Contents -- Preface -- Chapter 1: Europium III: Different Emission Spectra in Different Matrices, the Same Element -- Abstract -- Introduction -- Hydrolytic Sol-Gel Process -- Non-Hydrolytic Sol-Gel Process -- Characterization Techniques -- Non-Hydrolytic Sol-Gel Process -- Conclusion -- Acknowledgments -- References -- Chapter 2: Organic Europium Complexes and their Applications in Optoelectronic Devices -- 1. Introduction -- 1.1. Organic Light-Emitting Diodes -- 1.2. Organic Memory -- 1.3. Rare Earth Complexes in Organic LEDs and Memory -- 2. Europium Complexes in OLEDs -- 3. Europium Complexes in an Organic Memory -- 4. Summaries and Conclusion -- References -- Chapter 3: Europium: Compounds, Production and their Optical Applications -- Abstract -- 1. Introduction -- 2. Discovery -- 3. Resources -- 4. Resource Processing -- 4.1. Extraction of Bastnasite -- 4.2. Extraction of Monazite -- 4.3. Separating the Lanthanides -- 5. Destines -- 6. General Aspects of the Luminescence -- 6.1. Electronic Structure and Energy Levels -- 6.2. Radiative Transitions -- 6.3. Non-Radiative Transitions -- 6.4. Quenching -- 7. Luminescent materials -- 7.1. Inorganic Phosphors -- 7.1.1. Some commercial inorganic phosphors doped with europium -- 7.1.2. Some applications -- 7.2. Lanthanides Complexes -- 7.2.1. Europium β-diketonates complexes -- 7.2.2 Some technological applications -- 7.2.3. Some analytical applications -- 7.3. Lanthanide Based Hybrid Materials -- 8. Summary -- Acknowledgments -- References -- Chapter 4: The Development of Luminescence Properties of Eu3+-Doped Nanosized Materials -- Abstract -- 1. Introduction -- 2. Light-Induced Changes of CT Band of Eu3+ Doped Nanocrystals.

3. Site Symmetry of Eu3+ Doped Nanocrysals -- 4. The Dynamic Processes of Eu3+ Doped Nanocrystals -- 5. Thermal Quenching Properties of Eu3+ Doped Nanocrystals -- 6. The UCL Of Eu3+ in Oxide Nanocrystal -- 7. Spectral Hole Burning -- 8. Core-Shell Nanopcomposites Doped with Eu3+ -- 9. The Luminescence of Eu2+ in Nanocrystals -- References -- Chapter 5: Properties of Europium Complexes Doped Polymer Optical Materials -- Abstract -- Introduction -- Properties of Eu(DBM)3Phen doped PMMA -- X-Ray Diffraction Spectra and Thermal Analysis -- Excitation and Fluorescence Emission Spectra -- Metastable State Lifetime -- Near-Field Scanning Optical Microscopy Investigation -- Judd-Ofelt Analysis of Eu Complexs Doped Polymer -- Theoretical Background -- Radiative Properties of Eu(DBM)3Phen Doped PMMA -- The Influence of the Ligands -- Europium Complex with Dendritic Ligands Doped Polymethylvinylsiloxane -- Eu(DBM)3Phen Doped Polymer Optical Fiber and Planner Waveguide -- Amplified Spontaneous Emission (ASE) of Eu(DBM)3Phen Doped SI POF -- Optical Amplification of Eu(DBM)3Phen Doped SI POF -- Eu(DBM)3Phen Doped PMMA Film and Properties of its Planar Waveguide -- Conclusion -- Acknowledgment -- References -- Chatper 6: Europium in Phospholipid Nanoscaffolds for the Photophysical Detection of Antibiotic Traces in Solution -- Abstract -- Introduction -- Experimental Approach -- Materials -- Solution Behavior of Tetracyclines: Protonation Equilibria and Ph-Dependent Conformation -- Europium-Phospholipid Nanoscaffolds at Water-Air Interface -- Supported Phospholipid Langmuir-Blogett Films -- Biomimetic Nanoarchitectures Containing Europium Cations for Immobilization of TC in Solution -- Conclusions -- Acknowledgments -- References -- Chapter 7: Organic-Inorganic Emitting Materials Using Eu-Complex.

Department of Functional Materials Science, Graduate School of Science and Engineering, Saitama University. -- Abstract -- 1. Introduction -- 2. Principle and Problem of Europium-Complex -- 3. Sol-Gel Process for Encapsulation -- 4. Particle Type Encapsulated Material -- 4.1. Fabrication Process -- 4.2. Concentration of Catalyst Dependence -- 4.3. Concentration of Water and Ethanol Dependence -- 5. Particle Type Encapsulated Material -- 5.1. Fabrication Process -- 5.2. Concentration Dependence -- 6. Conclusion -- Acknowledgment -- Commentary -- References -- Chapter 8: Magnetic Phase Separation in the EuBxC1-x Observed by ESR -- 1 Kazan Physical-Technical Institute of the RAS, 420029, Kazan, Russia -- 2 Institute for Problems of Materials Science of NASU, 03680, Kiev, Ukraine -- Abstract -- Introduction -- Experimental -- Sample preparation and ESR measurements. -- Results and Discussion -- ESR in EuB6 -- ESR in EuB5.93C0.07 -- Conclusion -- Acknowledgment -- References -- Chapter 9: Research on Luminescent Characteristics of Organic Europium Complexes -- Abstract -- Introduction -- Experiment -- Results and Discussion -- Conclusion -- Acknowledgment -- References -- Chapter 10: Inelastic Channels Resonant Tunneling in Heterostructures EuS / PbS -- The Tula State Pedagogical University, Tula, 300026, Russia -- physics@tspu.tula.ru -- Chapter 11: Excitons in Superlattices on the Basis of Ferromagnetic Semiconductors: Rules of Selection -- Tula State Pedagogical University IT. L.N. Tolstogo Tula, 300026, Russia -- Index.