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Colour and the optical properties of materials [[electronic resource] ] : an exploration of the relationship between light, the optical properties of materials and colour / / Richard J.D. Tilley
Colour and the optical properties of materials [[electronic resource] ] : an exploration of the relationship between light, the optical properties of materials and colour / / Richard J.D. Tilley
Autore Tilley R. J. D
Edizione [2nd ed.]
Pubbl/distr/stampa Chichester, West Sussex, U.K., : Wiley, 2011
Descrizione fisica 1 online resource (472 p.)
Disciplina 535.6
Soggetto topico Light
Optics
Color
Soggetto genere / forma Electronic books.
ISBN 1-280-75100-2
9786613677839
0-470-97477-X
0-470-97476-1
Formato Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione eng
Nota di contenuto Preface. 1 Light and Colour. 1.1 Colour and light. 1.2 Colour and energy. 1.3 Light waves. 1.4 Interference. 1.5 Light waves and colour. 1.6 Black body radiation and incandescence. 1.7 The colour of incandescent objects. 1.8 Photons. 1.9 Lamps and lasers. 1.10 Vision. 1.11 Colour perception. 1.12 Additive coloration. 1.13 The interaction of light with a material. 1.14 Subtractive coloration. 1.15 Electronic "paper". 1.16 Appearance and transparency. Appendix 1.1 Definitions, units and conversion factors. Further reading. 2 Colours due to Refraction and Dispersion. 2.1 Refraction and the refractive index of a material. 2.2 Total internal reflection. 2.3 Refractive index and polarisability. 2.4 Refractive index and density. 2.5 Invisible animals, GRINS and mirages. 2.6 Dispersion and colours produced by dispersion. 2.7 Rainbows and halos. 2.8 Halos. 2.9 Fibre optics. 2.10 Negative refractive index materials. Further reading. 3 The Production of Colour by Reflection. 3.1 Reflection from a single surface. 3.2 Interference at a single thin film in air. 3.3 The colour of a single thin film in air. 3.4 The reflectivity of a single thin film in air. 3.5 The colour of a single thin film on a substrate. 3.6 The reflectivity of a single thin film on a substrate. 3.7 Low-reflection and high-reflection films. 3.8 Multiple thin films. 3.9 Fibre Bragg Gratings. 3.10 "Smart" windows. 3.11 Photonic engineering in nature. 3.12 Further reading. 3.13 Problems and exercises. Appendix 3.1 The colour of a thin film in white light. Further Reading. 4 Polarisation and crystals. 4.1 Polarisation of light. 4.2 Polarisation by reflection. 4.3 Polars. 4.4 Crystal symmetry and refractive index. 4.5 Double refraction: calcite as an example. 4.6 The description of double refraction effects. 4.7 Colour produced by polarisation and birefringence. 4.8 Pleochroism and dichroism. 4.9 Nonlinear effects. 4.10 Frequency matching and phase matching. 4.11 More on second harmonic generation. 4.12 Optical activity. 4.13 Liquid crystals. Further reading. 5 Colour due to Scattering. 5.1 Scattering and extinction. 5.2 Tyndall blue and Rayleigh scattering. 5.3 Blue skies, red sunsets. 5.4 Scattering and polarisation. 5.5 Mie scattering. 5.6 Blue eyes and some blue feathers. 5.7 Paints, sunscreens and related matters. 5.8 Multiple scattering. 5.9 Gold sols and ruby glass. 5.10 The Lycurgus Cup. Further reading. 6 Colour due to Diffraction. 6.1 Diffraction and colour production by a slit. 6.2 Diffraction and colour production by a rectangular aperture. 6.3 Diffraction and colour production by a circular aperture. 6.4 The diffraction limit of optical instruments. 6.5 Colour production by linear diffraction gratings. 6.6 Two-dimensional gratings. 6.7 Estimation of the wavelength of light by diffraction. 6.8 Diffraction by crystals and crystal-like structures. 6.9 Disordered diffraction gratings. 6.10 Diffraction by sub-wavelength structures. 6.11 Holograms. Further reading. 7 Colour from Atoms and Ions. 7.1 The spectra of atoms and ions. 7.2 Terms and levels. 7.3 Atomic spectra and chemical analysis. 7.4 Fraunhofer lines and stellar spectra. 7.5 Neon signs and early plasma displays. 7.6 The helium-neon laser. 7.7 Sodium and mercury street lights. 7.8 Transition metals and crystal field colours. 7.9 Crystal field splitting, energy levels and terms. 7.10 The colour of ruby. 7.11 Transition-metal-ion lasers. 7.12 Emerald, alexandrite and crystal field strength. 7.13 Crystal field colours in minerals and gemstones. 7.14 Colour as a structural probe. 7.15 Colours from lanthanide ions. 7.16 The neodymium (Nd3+) solid state laser: a four level laser. 7.17 Amplification of optical fibre signals. 7.18 Transition metal and lanthanide pigments. 7.19 Spectral hole formation. 7.20 Further reading. 7.21 Problems and exercises. Appendix 7.1 Electron configurations. Appendix 7.2 Terms and levels. Further Reading. 8 Colour from Molecules. 8.1 The energy levels of molecules. 8.2 The colours arising in some simple inorganic molecules. 8.3 The colour of water. 8.4 Chromophores, chromogens and auxochromes. 8.5 Conjugated bonds in organic molecules: the carotenoids. 8.6 Conjugated bonds circling metal atoms: porphyrins and phthalocyanines. 8.7 Naturally occurring colorants: flavonoid pigments. 8.8 Autumn leaves. 8.9 Some dyes and pigments. 8.10 Charge transfer colours. 8.11 Colour change sensors. 8.12 Dye lasers. 8.13 Photochromic organic molecules. Further reading. 9 Luminescence. 9.1 Luminescence. 9.2 Activators, sensitizers and fluorophores. 9.3 Atomic processes in photoluminescence. 9.4 Fluorescent lamps. 9.5 Plasma displays. 9.6 Cathodoluminescence and cathode ray tubes (CRTs). 9.7 Field emission displays (FEDs). 9.8 Phosphor electroluminescent displays. 9.9 Upconversion. 9.10 Quantum cutting. 9.11 Fluorescent molecules. 9.12 Fluorescent nanoparticles. 9.13 Fluorescent markers and sensors. 9.14 Chemiluminescence and Bioluminescence. 9.15 Triboluminescence. 9.16 Scintillators. Further reading. 10 Colour in Metals, Semiconductors and Insulators. 10.1 The colours of insulators. 10.2 Excitons. 10.3 Impurity colours in insulators. 10.4 Impurity colours in diamond. 10.5 Colour centres. 10.6 The colours of semiconductors. 10.7 The colours of semiconductor alloys. 10.8 Light emitting diodes (LEDs). 10.9 Semiconductor diode lasers. 10.10 Semiconductor nanostructures. 10.11 Organic semiconductors and electroluminescence. 10.12 Electrochromic films. 10.13 Photovoltaics. 10.14 Digital photography. 10.15 The colours of metals. 10.16 The colours of metal nanoparticles. 10.17 Extraordinary light transmission and plasmonic crystals. Further Reading. Index.
Record Nr. UNINA-9910139168003321
Tilley R. J. D  
Chichester, West Sussex, U.K., : Wiley, 2011
Materiale a stampa
Lo trovi qui: Univ. Federico II
Opac: Controlla la disponibilità qui
Colour and the optical properties of materials [[electronic resource] ] : an exploration of the relationship between light, the optical properties of materials and colour / / Richard J.D. Tilley
Colour and the optical properties of materials [[electronic resource] ] : an exploration of the relationship between light, the optical properties of materials and colour / / Richard J.D. Tilley
Autore Tilley R. J. D
Edizione [2nd ed.]
Pubbl/distr/stampa Chichester, West Sussex, U.K., : Wiley, 2011
Descrizione fisica 1 online resource (472 p.)
Disciplina 535.6
Soggetto topico Light
Optics
Color
ISBN 1-280-75100-2
9786613677839
0-470-97477-X
0-470-97476-1
Formato Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione eng
Nota di contenuto Preface. 1 Light and Colour. 1.1 Colour and light. 1.2 Colour and energy. 1.3 Light waves. 1.4 Interference. 1.5 Light waves and colour. 1.6 Black body radiation and incandescence. 1.7 The colour of incandescent objects. 1.8 Photons. 1.9 Lamps and lasers. 1.10 Vision. 1.11 Colour perception. 1.12 Additive coloration. 1.13 The interaction of light with a material. 1.14 Subtractive coloration. 1.15 Electronic "paper". 1.16 Appearance and transparency. Appendix 1.1 Definitions, units and conversion factors. Further reading. 2 Colours due to Refraction and Dispersion. 2.1 Refraction and the refractive index of a material. 2.2 Total internal reflection. 2.3 Refractive index and polarisability. 2.4 Refractive index and density. 2.5 Invisible animals, GRINS and mirages. 2.6 Dispersion and colours produced by dispersion. 2.7 Rainbows and halos. 2.8 Halos. 2.9 Fibre optics. 2.10 Negative refractive index materials. Further reading. 3 The Production of Colour by Reflection. 3.1 Reflection from a single surface. 3.2 Interference at a single thin film in air. 3.3 The colour of a single thin film in air. 3.4 The reflectivity of a single thin film in air. 3.5 The colour of a single thin film on a substrate. 3.6 The reflectivity of a single thin film on a substrate. 3.7 Low-reflection and high-reflection films. 3.8 Multiple thin films. 3.9 Fibre Bragg Gratings. 3.10 "Smart" windows. 3.11 Photonic engineering in nature. 3.12 Further reading. 3.13 Problems and exercises. Appendix 3.1 The colour of a thin film in white light. Further Reading. 4 Polarisation and crystals. 4.1 Polarisation of light. 4.2 Polarisation by reflection. 4.3 Polars. 4.4 Crystal symmetry and refractive index. 4.5 Double refraction: calcite as an example. 4.6 The description of double refraction effects. 4.7 Colour produced by polarisation and birefringence. 4.8 Pleochroism and dichroism. 4.9 Nonlinear effects. 4.10 Frequency matching and phase matching. 4.11 More on second harmonic generation. 4.12 Optical activity. 4.13 Liquid crystals. Further reading. 5 Colour due to Scattering. 5.1 Scattering and extinction. 5.2 Tyndall blue and Rayleigh scattering. 5.3 Blue skies, red sunsets. 5.4 Scattering and polarisation. 5.5 Mie scattering. 5.6 Blue eyes and some blue feathers. 5.7 Paints, sunscreens and related matters. 5.8 Multiple scattering. 5.9 Gold sols and ruby glass. 5.10 The Lycurgus Cup. Further reading. 6 Colour due to Diffraction. 6.1 Diffraction and colour production by a slit. 6.2 Diffraction and colour production by a rectangular aperture. 6.3 Diffraction and colour production by a circular aperture. 6.4 The diffraction limit of optical instruments. 6.5 Colour production by linear diffraction gratings. 6.6 Two-dimensional gratings. 6.7 Estimation of the wavelength of light by diffraction. 6.8 Diffraction by crystals and crystal-like structures. 6.9 Disordered diffraction gratings. 6.10 Diffraction by sub-wavelength structures. 6.11 Holograms. Further reading. 7 Colour from Atoms and Ions. 7.1 The spectra of atoms and ions. 7.2 Terms and levels. 7.3 Atomic spectra and chemical analysis. 7.4 Fraunhofer lines and stellar spectra. 7.5 Neon signs and early plasma displays. 7.6 The helium-neon laser. 7.7 Sodium and mercury street lights. 7.8 Transition metals and crystal field colours. 7.9 Crystal field splitting, energy levels and terms. 7.10 The colour of ruby. 7.11 Transition-metal-ion lasers. 7.12 Emerald, alexandrite and crystal field strength. 7.13 Crystal field colours in minerals and gemstones. 7.14 Colour as a structural probe. 7.15 Colours from lanthanide ions. 7.16 The neodymium (Nd3+) solid state laser: a four level laser. 7.17 Amplification of optical fibre signals. 7.18 Transition metal and lanthanide pigments. 7.19 Spectral hole formation. 7.20 Further reading. 7.21 Problems and exercises. Appendix 7.1 Electron configurations. Appendix 7.2 Terms and levels. Further Reading. 8 Colour from Molecules. 8.1 The energy levels of molecules. 8.2 The colours arising in some simple inorganic molecules. 8.3 The colour of water. 8.4 Chromophores, chromogens and auxochromes. 8.5 Conjugated bonds in organic molecules: the carotenoids. 8.6 Conjugated bonds circling metal atoms: porphyrins and phthalocyanines. 8.7 Naturally occurring colorants: flavonoid pigments. 8.8 Autumn leaves. 8.9 Some dyes and pigments. 8.10 Charge transfer colours. 8.11 Colour change sensors. 8.12 Dye lasers. 8.13 Photochromic organic molecules. Further reading. 9 Luminescence. 9.1 Luminescence. 9.2 Activators, sensitizers and fluorophores. 9.3 Atomic processes in photoluminescence. 9.4 Fluorescent lamps. 9.5 Plasma displays. 9.6 Cathodoluminescence and cathode ray tubes (CRTs). 9.7 Field emission displays (FEDs). 9.8 Phosphor electroluminescent displays. 9.9 Upconversion. 9.10 Quantum cutting. 9.11 Fluorescent molecules. 9.12 Fluorescent nanoparticles. 9.13 Fluorescent markers and sensors. 9.14 Chemiluminescence and Bioluminescence. 9.15 Triboluminescence. 9.16 Scintillators. Further reading. 10 Colour in Metals, Semiconductors and Insulators. 10.1 The colours of insulators. 10.2 Excitons. 10.3 Impurity colours in insulators. 10.4 Impurity colours in diamond. 10.5 Colour centres. 10.6 The colours of semiconductors. 10.7 The colours of semiconductor alloys. 10.8 Light emitting diodes (LEDs). 10.9 Semiconductor diode lasers. 10.10 Semiconductor nanostructures. 10.11 Organic semiconductors and electroluminescence. 10.12 Electrochromic films. 10.13 Photovoltaics. 10.14 Digital photography. 10.15 The colours of metals. 10.16 The colours of metal nanoparticles. 10.17 Extraordinary light transmission and plasmonic crystals. Further Reading. Index.
Record Nr. UNINA-9910830317103321
Tilley R. J. D  
Chichester, West Sussex, U.K., : Wiley, 2011
Materiale a stampa
Lo trovi qui: Univ. Federico II
Opac: Controlla la disponibilità qui
Colour and the optical properties of materials [[electronic resource] ] : an exploration of the relationship between light, the optical properties of materials and colour / / Richard J.D. Tilley
Colour and the optical properties of materials [[electronic resource] ] : an exploration of the relationship between light, the optical properties of materials and colour / / Richard J.D. Tilley
Autore Tilley R. J. D
Edizione [2nd ed.]
Pubbl/distr/stampa Chichester, West Sussex, U.K., : Wiley, 2011
Descrizione fisica 1 online resource (472 p.)
Disciplina 535.6
Soggetto topico Light
Optics
Color
ISBN 1-280-75100-2
9786613677839
0-470-97477-X
0-470-97476-1
Formato Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione eng
Nota di contenuto Preface. 1 Light and Colour. 1.1 Colour and light. 1.2 Colour and energy. 1.3 Light waves. 1.4 Interference. 1.5 Light waves and colour. 1.6 Black body radiation and incandescence. 1.7 The colour of incandescent objects. 1.8 Photons. 1.9 Lamps and lasers. 1.10 Vision. 1.11 Colour perception. 1.12 Additive coloration. 1.13 The interaction of light with a material. 1.14 Subtractive coloration. 1.15 Electronic "paper". 1.16 Appearance and transparency. Appendix 1.1 Definitions, units and conversion factors. Further reading. 2 Colours due to Refraction and Dispersion. 2.1 Refraction and the refractive index of a material. 2.2 Total internal reflection. 2.3 Refractive index and polarisability. 2.4 Refractive index and density. 2.5 Invisible animals, GRINS and mirages. 2.6 Dispersion and colours produced by dispersion. 2.7 Rainbows and halos. 2.8 Halos. 2.9 Fibre optics. 2.10 Negative refractive index materials. Further reading. 3 The Production of Colour by Reflection. 3.1 Reflection from a single surface. 3.2 Interference at a single thin film in air. 3.3 The colour of a single thin film in air. 3.4 The reflectivity of a single thin film in air. 3.5 The colour of a single thin film on a substrate. 3.6 The reflectivity of a single thin film on a substrate. 3.7 Low-reflection and high-reflection films. 3.8 Multiple thin films. 3.9 Fibre Bragg Gratings. 3.10 "Smart" windows. 3.11 Photonic engineering in nature. 3.12 Further reading. 3.13 Problems and exercises. Appendix 3.1 The colour of a thin film in white light. Further Reading. 4 Polarisation and crystals. 4.1 Polarisation of light. 4.2 Polarisation by reflection. 4.3 Polars. 4.4 Crystal symmetry and refractive index. 4.5 Double refraction: calcite as an example. 4.6 The description of double refraction effects. 4.7 Colour produced by polarisation and birefringence. 4.8 Pleochroism and dichroism. 4.9 Nonlinear effects. 4.10 Frequency matching and phase matching. 4.11 More on second harmonic generation. 4.12 Optical activity. 4.13 Liquid crystals. Further reading. 5 Colour due to Scattering. 5.1 Scattering and extinction. 5.2 Tyndall blue and Rayleigh scattering. 5.3 Blue skies, red sunsets. 5.4 Scattering and polarisation. 5.5 Mie scattering. 5.6 Blue eyes and some blue feathers. 5.7 Paints, sunscreens and related matters. 5.8 Multiple scattering. 5.9 Gold sols and ruby glass. 5.10 The Lycurgus Cup. Further reading. 6 Colour due to Diffraction. 6.1 Diffraction and colour production by a slit. 6.2 Diffraction and colour production by a rectangular aperture. 6.3 Diffraction and colour production by a circular aperture. 6.4 The diffraction limit of optical instruments. 6.5 Colour production by linear diffraction gratings. 6.6 Two-dimensional gratings. 6.7 Estimation of the wavelength of light by diffraction. 6.8 Diffraction by crystals and crystal-like structures. 6.9 Disordered diffraction gratings. 6.10 Diffraction by sub-wavelength structures. 6.11 Holograms. Further reading. 7 Colour from Atoms and Ions. 7.1 The spectra of atoms and ions. 7.2 Terms and levels. 7.3 Atomic spectra and chemical analysis. 7.4 Fraunhofer lines and stellar spectra. 7.5 Neon signs and early plasma displays. 7.6 The helium-neon laser. 7.7 Sodium and mercury street lights. 7.8 Transition metals and crystal field colours. 7.9 Crystal field splitting, energy levels and terms. 7.10 The colour of ruby. 7.11 Transition-metal-ion lasers. 7.12 Emerald, alexandrite and crystal field strength. 7.13 Crystal field colours in minerals and gemstones. 7.14 Colour as a structural probe. 7.15 Colours from lanthanide ions. 7.16 The neodymium (Nd3+) solid state laser: a four level laser. 7.17 Amplification of optical fibre signals. 7.18 Transition metal and lanthanide pigments. 7.19 Spectral hole formation. 7.20 Further reading. 7.21 Problems and exercises. Appendix 7.1 Electron configurations. Appendix 7.2 Terms and levels. Further Reading. 8 Colour from Molecules. 8.1 The energy levels of molecules. 8.2 The colours arising in some simple inorganic molecules. 8.3 The colour of water. 8.4 Chromophores, chromogens and auxochromes. 8.5 Conjugated bonds in organic molecules: the carotenoids. 8.6 Conjugated bonds circling metal atoms: porphyrins and phthalocyanines. 8.7 Naturally occurring colorants: flavonoid pigments. 8.8 Autumn leaves. 8.9 Some dyes and pigments. 8.10 Charge transfer colours. 8.11 Colour change sensors. 8.12 Dye lasers. 8.13 Photochromic organic molecules. Further reading. 9 Luminescence. 9.1 Luminescence. 9.2 Activators, sensitizers and fluorophores. 9.3 Atomic processes in photoluminescence. 9.4 Fluorescent lamps. 9.5 Plasma displays. 9.6 Cathodoluminescence and cathode ray tubes (CRTs). 9.7 Field emission displays (FEDs). 9.8 Phosphor electroluminescent displays. 9.9 Upconversion. 9.10 Quantum cutting. 9.11 Fluorescent molecules. 9.12 Fluorescent nanoparticles. 9.13 Fluorescent markers and sensors. 9.14 Chemiluminescence and Bioluminescence. 9.15 Triboluminescence. 9.16 Scintillators. Further reading. 10 Colour in Metals, Semiconductors and Insulators. 10.1 The colours of insulators. 10.2 Excitons. 10.3 Impurity colours in insulators. 10.4 Impurity colours in diamond. 10.5 Colour centres. 10.6 The colours of semiconductors. 10.7 The colours of semiconductor alloys. 10.8 Light emitting diodes (LEDs). 10.9 Semiconductor diode lasers. 10.10 Semiconductor nanostructures. 10.11 Organic semiconductors and electroluminescence. 10.12 Electrochromic films. 10.13 Photovoltaics. 10.14 Digital photography. 10.15 The colours of metals. 10.16 The colours of metal nanoparticles. 10.17 Extraordinary light transmission and plasmonic crystals. Further Reading. Index.
Record Nr. UNINA-9910840533003321
Tilley R. J. D  
Chichester, West Sussex, U.K., : Wiley, 2011
Materiale a stampa
Lo trovi qui: Univ. Federico II
Opac: Controlla la disponibilità qui
Defects in solids [[electronic resource] /] / Richard J.D. Tilley
Defects in solids [[electronic resource] /] / Richard J.D. Tilley
Autore Tilley R. J. D
Pubbl/distr/stampa Hoboken, N.J., : Wiley, c2008
Descrizione fisica 1 online resource (549 p.)
Disciplina 620.1/1
620.11
Collana Special Topics in Inorganic Chemistry
Soggetto topico Solids - Defects
Solids - Electric properties
Solids - Magnetic properties
Solids - Optical properties
ISBN 1-283-20329-4
9786613203298
0-470-38075-6
0-470-38073-X
Formato Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione eng
Nota di contenuto DEFECTS IN SOLIDS; CONTENTS; Preface; 1. Point Defects; 1.1 Introduction; 1.2 Point and Electronic Defects in Crystalline Solids; 1.3 Electronic Properties: Doped Silicon and Germanium as Examples; 1.4 Optical Properties: F Centers and Ruby as Examples; 1.5 Bulk Properties; 1.5.1 Unit Cell Dimensions; 1.5.2 Density; 1.5.3 Volume; 1.5.4 Young's Modulus (the Elastic Modulus); 1.6 Thermoelectric Properties: The Seebeck Coefficient as an Example; 1.7 Point Defect Notation; 1.8 Charges on Defects; 1.8.1 Electrons and Electron Holes; 1.8.2 Atomic and Ionic Defects
1.9 Balanced Populations of Point Defects: Schottky and Frenkel Defects 1.9.1 Schottky Defects; 1.9.2 Frenkel Defects; 1.10 Antisite Defects; 1.11 Defect Formation and Reaction Equations; 1.11.1 Addition and Subtraction of Atoms; 1.11.2 Equation Formalism; 1.11.3 Formation of Antisite Defects; 1.11.4 Nickel Oxide; 1.11.5 Cadmium Oxide; 1.11.6 Calcia-stabilized Zirconia; 1.11.7 Ternary Oxides; 1.12 Combinations of Point Defects in Pure Materials; 1.13 Structural Consequences of Point Defect Populations; 1.14 Answers to Introductory Questions; Problems and Exercises; References; Further Reading
2. Intrinsic Point Defects in Stoichiometric Compounds 2.1 Equilibrium Population of Vacancies in a Monatomic Crystal; 2.2 Equilibrium Population of Self-Interstitials in a Monatomic Crystal; 2.3 Equilibrium Population of Schottky Defects in a Crystal; 2.4 Lithium Iodide Battery; 2.5 Equilibrium Population of Frenkel Defects in a Crystal; 2.6 Photographic Film; 2.7 Photochromic Glasses; 2.8 Equilibrium Population of Antisite Defects in a Crystal; 2.9 Intrinsic Defects: Trends and Further Considerations; 2.10 Computation of Defect Energies; 2.10.1 Defect Calculations
2.10.2 Point Defect Interactions 2.10.3 Atomistic Simulation; 2.10.4 The Shell Model; 2.10.5 Defect Formation Energy; 2.10.6 Quantum Mechanical Calculations; 2.11 Answers to Introductory Questions; Problems and Exercises; References; Further Reading; 3. Extended Defects; 3.1 Dislocations; 3.2 Edge Dislocations; 3.3 Screw Dislocations; 3.4 Mixed Dislocations; 3.5 Unit and Partial Dislocations; 3.6 Multiplication of Dislocations; 3.7 Interaction of Dislocations and Point Defects; 3.7.1 Dislocation Loops; 3.7.2 Dislocation Climb; 3.7.3 Decoration of Dislocations
3.8 Dislocations in Nonmetallic Crystals 3.9 Internal Boundaries; 3.10 Low-Angle Grain Boundaries; 3.11 Twin Boundaries; 3.12 Antiphase Boundaries; 3.13 Domains and Ferroic Materials; 3.13.1 Magnetic Structures; 3.13.2 Ferroelectric Structures; 3.13.3 Ferroic Structures; 3.14 External Surfaces and Grain Boundaries; 3.14.1 Optical Characteristics of Polycrystalline Solids; 3.14.2 Electronic Properties of Interfaces; 3.14.3 Varistors; 3.14.4 Positive Temperature Coefficient Thermistors; 3.15 Volume Defects and Precipitates; 3.16 Answers to Introductory Questions; Problems and Exercises
Further Reading
Record Nr. UNINA-9910144103303321
Tilley R. J. D  
Hoboken, N.J., : Wiley, c2008
Materiale a stampa
Lo trovi qui: Univ. Federico II
Opac: Controlla la disponibilità qui
Defects in solids [[electronic resource] /] / Richard J.D. Tilley
Defects in solids [[electronic resource] /] / Richard J.D. Tilley
Autore Tilley R. J. D
Pubbl/distr/stampa Hoboken, N.J., : Wiley, c2008
Descrizione fisica 1 online resource (549 p.)
Disciplina 620.1/1
620.11
Collana Special Topics in Inorganic Chemistry
Soggetto topico Solids - Defects
Solids - Electric properties
Solids - Magnetic properties
Solids - Optical properties
ISBN 1-283-20329-4
9786613203298
0-470-38075-6
0-470-38073-X
Formato Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione eng
Nota di contenuto DEFECTS IN SOLIDS; CONTENTS; Preface; 1. Point Defects; 1.1 Introduction; 1.2 Point and Electronic Defects in Crystalline Solids; 1.3 Electronic Properties: Doped Silicon and Germanium as Examples; 1.4 Optical Properties: F Centers and Ruby as Examples; 1.5 Bulk Properties; 1.5.1 Unit Cell Dimensions; 1.5.2 Density; 1.5.3 Volume; 1.5.4 Young's Modulus (the Elastic Modulus); 1.6 Thermoelectric Properties: The Seebeck Coefficient as an Example; 1.7 Point Defect Notation; 1.8 Charges on Defects; 1.8.1 Electrons and Electron Holes; 1.8.2 Atomic and Ionic Defects
1.9 Balanced Populations of Point Defects: Schottky and Frenkel Defects 1.9.1 Schottky Defects; 1.9.2 Frenkel Defects; 1.10 Antisite Defects; 1.11 Defect Formation and Reaction Equations; 1.11.1 Addition and Subtraction of Atoms; 1.11.2 Equation Formalism; 1.11.3 Formation of Antisite Defects; 1.11.4 Nickel Oxide; 1.11.5 Cadmium Oxide; 1.11.6 Calcia-stabilized Zirconia; 1.11.7 Ternary Oxides; 1.12 Combinations of Point Defects in Pure Materials; 1.13 Structural Consequences of Point Defect Populations; 1.14 Answers to Introductory Questions; Problems and Exercises; References; Further Reading
2. Intrinsic Point Defects in Stoichiometric Compounds 2.1 Equilibrium Population of Vacancies in a Monatomic Crystal; 2.2 Equilibrium Population of Self-Interstitials in a Monatomic Crystal; 2.3 Equilibrium Population of Schottky Defects in a Crystal; 2.4 Lithium Iodide Battery; 2.5 Equilibrium Population of Frenkel Defects in a Crystal; 2.6 Photographic Film; 2.7 Photochromic Glasses; 2.8 Equilibrium Population of Antisite Defects in a Crystal; 2.9 Intrinsic Defects: Trends and Further Considerations; 2.10 Computation of Defect Energies; 2.10.1 Defect Calculations
2.10.2 Point Defect Interactions 2.10.3 Atomistic Simulation; 2.10.4 The Shell Model; 2.10.5 Defect Formation Energy; 2.10.6 Quantum Mechanical Calculations; 2.11 Answers to Introductory Questions; Problems and Exercises; References; Further Reading; 3. Extended Defects; 3.1 Dislocations; 3.2 Edge Dislocations; 3.3 Screw Dislocations; 3.4 Mixed Dislocations; 3.5 Unit and Partial Dislocations; 3.6 Multiplication of Dislocations; 3.7 Interaction of Dislocations and Point Defects; 3.7.1 Dislocation Loops; 3.7.2 Dislocation Climb; 3.7.3 Decoration of Dislocations
3.8 Dislocations in Nonmetallic Crystals 3.9 Internal Boundaries; 3.10 Low-Angle Grain Boundaries; 3.11 Twin Boundaries; 3.12 Antiphase Boundaries; 3.13 Domains and Ferroic Materials; 3.13.1 Magnetic Structures; 3.13.2 Ferroelectric Structures; 3.13.3 Ferroic Structures; 3.14 External Surfaces and Grain Boundaries; 3.14.1 Optical Characteristics of Polycrystalline Solids; 3.14.2 Electronic Properties of Interfaces; 3.14.3 Varistors; 3.14.4 Positive Temperature Coefficient Thermistors; 3.15 Volume Defects and Precipitates; 3.16 Answers to Introductory Questions; Problems and Exercises
Further Reading
Record Nr. UNINA-9910830722503321
Tilley R. J. D  
Hoboken, N.J., : Wiley, c2008
Materiale a stampa
Lo trovi qui: Univ. Federico II
Opac: Controlla la disponibilità qui
Defects in solids [[electronic resource] /] / Richard J.D. Tilley
Defects in solids [[electronic resource] /] / Richard J.D. Tilley
Autore Tilley R. J. D
Pubbl/distr/stampa Hoboken, N.J., : Wiley, c2008
Descrizione fisica 1 online resource (549 p.)
Disciplina 620.1/1
620.11
Collana Special Topics in Inorganic Chemistry
Soggetto topico Solids - Defects
Solids - Electric properties
Solids - Magnetic properties
Solids - Optical properties
ISBN 1-283-20329-4
9786613203298
0-470-38075-6
0-470-38073-X
Formato Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione eng
Nota di contenuto DEFECTS IN SOLIDS; CONTENTS; Preface; 1. Point Defects; 1.1 Introduction; 1.2 Point and Electronic Defects in Crystalline Solids; 1.3 Electronic Properties: Doped Silicon and Germanium as Examples; 1.4 Optical Properties: F Centers and Ruby as Examples; 1.5 Bulk Properties; 1.5.1 Unit Cell Dimensions; 1.5.2 Density; 1.5.3 Volume; 1.5.4 Young's Modulus (the Elastic Modulus); 1.6 Thermoelectric Properties: The Seebeck Coefficient as an Example; 1.7 Point Defect Notation; 1.8 Charges on Defects; 1.8.1 Electrons and Electron Holes; 1.8.2 Atomic and Ionic Defects
1.9 Balanced Populations of Point Defects: Schottky and Frenkel Defects 1.9.1 Schottky Defects; 1.9.2 Frenkel Defects; 1.10 Antisite Defects; 1.11 Defect Formation and Reaction Equations; 1.11.1 Addition and Subtraction of Atoms; 1.11.2 Equation Formalism; 1.11.3 Formation of Antisite Defects; 1.11.4 Nickel Oxide; 1.11.5 Cadmium Oxide; 1.11.6 Calcia-stabilized Zirconia; 1.11.7 Ternary Oxides; 1.12 Combinations of Point Defects in Pure Materials; 1.13 Structural Consequences of Point Defect Populations; 1.14 Answers to Introductory Questions; Problems and Exercises; References; Further Reading
2. Intrinsic Point Defects in Stoichiometric Compounds 2.1 Equilibrium Population of Vacancies in a Monatomic Crystal; 2.2 Equilibrium Population of Self-Interstitials in a Monatomic Crystal; 2.3 Equilibrium Population of Schottky Defects in a Crystal; 2.4 Lithium Iodide Battery; 2.5 Equilibrium Population of Frenkel Defects in a Crystal; 2.6 Photographic Film; 2.7 Photochromic Glasses; 2.8 Equilibrium Population of Antisite Defects in a Crystal; 2.9 Intrinsic Defects: Trends and Further Considerations; 2.10 Computation of Defect Energies; 2.10.1 Defect Calculations
2.10.2 Point Defect Interactions 2.10.3 Atomistic Simulation; 2.10.4 The Shell Model; 2.10.5 Defect Formation Energy; 2.10.6 Quantum Mechanical Calculations; 2.11 Answers to Introductory Questions; Problems and Exercises; References; Further Reading; 3. Extended Defects; 3.1 Dislocations; 3.2 Edge Dislocations; 3.3 Screw Dislocations; 3.4 Mixed Dislocations; 3.5 Unit and Partial Dislocations; 3.6 Multiplication of Dislocations; 3.7 Interaction of Dislocations and Point Defects; 3.7.1 Dislocation Loops; 3.7.2 Dislocation Climb; 3.7.3 Decoration of Dislocations
3.8 Dislocations in Nonmetallic Crystals 3.9 Internal Boundaries; 3.10 Low-Angle Grain Boundaries; 3.11 Twin Boundaries; 3.12 Antiphase Boundaries; 3.13 Domains and Ferroic Materials; 3.13.1 Magnetic Structures; 3.13.2 Ferroelectric Structures; 3.13.3 Ferroic Structures; 3.14 External Surfaces and Grain Boundaries; 3.14.1 Optical Characteristics of Polycrystalline Solids; 3.14.2 Electronic Properties of Interfaces; 3.14.3 Varistors; 3.14.4 Positive Temperature Coefficient Thermistors; 3.15 Volume Defects and Precipitates; 3.16 Answers to Introductory Questions; Problems and Exercises
Further Reading
Record Nr. UNINA-9910841156403321
Tilley R. J. D  
Hoboken, N.J., : Wiley, c2008
Materiale a stampa
Lo trovi qui: Univ. Federico II
Opac: Controlla la disponibilità qui
Understanding solids [[electronic resource] ] : the science of materials / / Richard J.D. Tilley
Understanding solids [[electronic resource] ] : the science of materials / / Richard J.D. Tilley
Autore Tilley R. J. D
Edizione [2nd ed.]
Pubbl/distr/stampa Chichester [England], : John Wiley & Sons Inc., 2013
Descrizione fisica 1 online resource (1166 p.)
Disciplina 620.1/1
Soggetto topico Materials science
Solids
Soggetto genere / forma Electronic books.
ISBN 1-299-40271-2
1-118-42344-5
Formato Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione eng
Nota di contenuto pt. 1. Structures and microstructures -- pt. 2. Classes of materials -- pt. 3. Reactions and transformations -- pt. 4. Physical properties -- pt. 5. Nuclear properties of solids.
Record Nr. UNINA-9910452374603321
Tilley R. J. D  
Chichester [England], : John Wiley & Sons Inc., 2013
Materiale a stampa
Lo trovi qui: Univ. Federico II
Opac: Controlla la disponibilità qui
Understanding solids [[electronic resource] ] : the science of materials / / Richard J.D. Tilley
Understanding solids [[electronic resource] ] : the science of materials / / Richard J.D. Tilley
Autore Tilley R. J. D
Edizione [2nd ed.]
Pubbl/distr/stampa Chichester [England], : John Wiley & Sons Inc., 2013
Descrizione fisica xx, 556 p. : ill
Disciplina 620.1/1
Soggetto topico Materials science
Solids
ISBN 1118423445
9781118423448
Formato Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione eng
Nota di contenuto pt. 1. Structures and microstructures -- pt. 2. Classes of materials -- pt. 3. Reactions and transformations -- pt. 4. Physical properties -- pt. 5. Nuclear properties of solids.
Record Nr. UNINA-9910795966103321
Tilley R. J. D  
Chichester [England], : John Wiley & Sons Inc., 2013
Materiale a stampa
Lo trovi qui: Univ. Federico II
Opac: Controlla la disponibilità qui
Understanding solids [[electronic resource] ] : the science of materials / / Richard J.D. Tilley
Understanding solids [[electronic resource] ] : the science of materials / / Richard J.D. Tilley
Autore Tilley R. J. D
Edizione [2nd ed.]
Pubbl/distr/stampa Chichester [England], : John Wiley & Sons Inc., 2013
Descrizione fisica xx, 556 p. : ill
Disciplina 620.1/1
Soggetto topico Materials science
Solids
ISBN 1118423445
9781118423448
Formato Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione eng
Nota di contenuto pt. 1. Structures and microstructures -- pt. 2. Classes of materials -- pt. 3. Reactions and transformations -- pt. 4. Physical properties -- pt. 5. Nuclear properties of solids.
Record Nr. UNINA-9910819765003321
Tilley R. J. D  
Chichester [England], : John Wiley & Sons Inc., 2013
Materiale a stampa
Lo trovi qui: Univ. Federico II
Opac: Controlla la disponibilità qui