Photonic and Electronic Properties of Fluoride Materials Progress in Fluorine Science Series Progress in Fluorine Science Series
Coordonnateurs : Tressaud Alain, Poeppelmeier Kenneth R.
Photonic and Electronic Properties of Fluoride Materials: Progress in Fluorine Science, the first volume in this new Elsevier series, provides an overview of the important optical, magnetic, and non-linear properties of fluoride materials. Beginning with a brief review of relevant synthesis methods from single crystals to nanopowders, this volume offers valuable insight for inorganic chemistry and materials science researchers. Edited and written by leaders in the field, this book explores the practical aspects of working with these materials, presenting a large number of examples from inorganic fluorides in which the type of bonding occurring between fluorine and transition metals (either d- or 4f-series) give rise to peculiar properties in many fundamental and applicative domains. This one-of-a-kind resource also includes several chapters covering functional organic fluorides used in nano-electronics, in particular in liquid crystal devices, in organic light-emitting diodes, or in organic dyes for sensitized solar cells. The book describes major advances and breakthroughs achieved by the use of fluoride materials in important domains such as superconductivity, luminescence, laser properties, multiferroism, transport properties, and more recently, in fluoro-perovskite for dye-sensitized solar cells and inorganic fluoride materials for NLO, and supports future development in these varied and key areas. The book is edited by Alain Tressaud, past chair and founder of the CNRS French Fluorine Network. Each book in the collection includes the work of highly-respected volume editors and contributors from both academia and industry to bring valuable and varied content to this active field.
1. Introduction to the Series “Progress in Fluorine Science
Part One. Synthesis
2. Elaboration of Nanofluorides and Ceramics for Optical and Laser Applications
Part Two. Optical Properties
3. Upconversion Phenomena in Nanofluorides
4. Optical Properties of Fluoride Transparent Ceramics
5. Synthesis and Characterization of F-Doped Zinc Oxides, Al-Doped Zinc Hydroxyfluoride, and Oxide–Fluoride Composites for Transparent Visible/Infrared Absorbers
6. Fluorine-Containing Beryllium Borates as Nonlinear Optical Crystals for Deep-Ultraviolet Laser Generation
7. Fluorescence in Nanostructured Oxyfluoride Glasses Doped with Rare Earth Ions
8. Fluorinated Nematic Liquid Crystals: Design, Synthesis, and Properties
9. Molecular Engineering of F-Based Iridium(III) Complexes as a Phosphorescent Emitter
10. Zinc Hydroxyfluoride (ZnOHF) Nanostructure as Photoelectrode of Quantum Dot-Sensitized Solar Cells
Part Three. Magnetic Properties
11. Molecular Fluoride-Bridged 3d-4f Complexes and Their Magnetic Properties
12. Unique Silver(II) Fluorides: The Emerging Electronic and Magnetic Materials
13. Magnetic Properties of Transition Metal Fluoride Perovskites
14. Multiferroism in Fluorides
Part Four. Non-linear Properties
15. Frequency-Doubling Oxide Fluorides, Borate Fluorides, and Fluorooxoborates
16. Ferroelastic and Ferroelectric Phase Transitions in Fluoro- and Oxyfluorometallates
17. Group Theoretical Approach on Possible Magnetoelectric Fluorides
Part Five. Superconductor Properties
18. Modification of Magnetic and Electronic Properties, in Particular Superconductivity, by Low Temperature Insertion of Fluorine into Oxides
19. Superconductivity in Iron Oxypnictide Induced by F-Doping
Part Six. Ionic Conductors
20. Ionic Conductivity of Nanocrystalline Metal Fluorides
21. Nonstoichiometric Single Crystals M1−xRxF2+x and R1−yMyF3−y (M =Ca, Sr, Ba: R=Rare Earth Elements) as Fluorine-Ionic Conductive Solid Electrolytes
Researchers in inorganic chemistry and materials science
Kenneth Poeppelmeier
Kenneth Poeppelmeier studied chemistry at the University of Missouri-Columbia from 1967 to 1971 (B.S. Chemistry). From 1971 to 1974, he was an Instructor in Chemistry at Samoa College in Western Samoa as a United States Peace Corps volunteer. He joined the research group of John Corbett at Iowa State University after leaving the Peace Corps and received his Ph.D. in 1978. He then joined the research staff of Exxon Research and Engineering Company, Corporate Research Science Laboratory, where he worked with John Longo and Allan Jacobson on the synthesis and characterization of mixed metal oxides and their application in heterogeneous catalysis. He joined the chemistry faculty of Northwestern University in 1984 where he is now the Charles E. and Emma H. Morrison Professor of Chemistry at Northwestern University and a NAISE Fellow joint with Northwestern Universi
- Provides unique coverage of the physical properties of fluoride materials for chemists and material scientists
- Begins with a brief review of relevant synthesis methods from single crystals to nanopowders
- Includes valuable information about functional organic fluorides used in nano-electronics, in particular in liquid crystal devices, in organic light-emitting diodes, or in organic dyes for sensitized solar cells
Date de parution : 03-2016
Ouvrage de 530 p.
15x22.8 cm
Thèmes de Photonic and Electronic Properties of Fluoride Materials :
Mots-clés :
Alkali metals; Ancillary ligand; Borate fluorides; Bulk superconductivity; Charge order; Computational chemistry; Core�shell particles; Crystal growth; Crystal structure; Cyclometalated ligand; Deep-UV lasers; Deep-UV nonlinear optical crystal; Defect crystal structure; Display technology; EELS; Emitter; Ex-situ powder-in-tube (PIT) method; F-doped oxides; Ferroelasticity; Ferroelectricity; Fluorescence; Fluoride bridging; Fluoride ion batteries; Fluoride ion selective electrode; Fluoride ion; Fluoride nanocrystals; Fluoride-based beryllium borates; Fluorides; Fluorination; Fluorine doping; Fluorine; Fluorine-ionic conductive solid electrolytes; Fluorite; Fluorooxoborates; Fluororganic chemistry; Frequency-doubling materials; Glass-ceramics; Grain boundary; Group theory; Hot forming; Hot pressing; Inhomogeneous distribution; Inorganic fluorides; Ionic conductivity; Iridium complex; Iron-based superconductors; Jahn�Teller effect; K2; LaFeAsO; Lanthanide; Laser ceramics; Layered perovskite; Lifetimes; Liquid crystals; Luminophores; Magnetic properties; Magnetism; Magnetocaloric effect; Magnetoelectricity; Metal fluoride composites; Multiferroics; Nanofluorides; Nanostructures; Near-infrared absorption; Neutron diffraction; NiF4; Nonstoichiometry; Optical properties; Orbital ordering; Organic light-emitting diode (OLED)Phosphorescence; Perovskite; Quantum dot-sensitized solar cells; Rare earth ions; Rare earth�doped fluorides; Rare earth�doped nanoparticles; Rare earth; Ruddlesden�Popper phases; Scintillators; Semiconducting properties; Silver; SmFeAsO; Solid-state laser; Stereoelectronic effects; Structure�property relationships; Superconducting critical current; Superconducting critical magnetic field; Superconducting wires; Superconductivity; Superexchange coupling; Surface chemistry; Synthesis; Tetragonal tungsten bronze; Transparent ceramics; Transparent conductive oxides (TCOs)Zinc hydroxyfluoride; Tysonite; Upconversion; XMCD; ZnOHF
