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200 10$aOptical properties of solids /$fMark Fox
205   $aSecond edition.
210  1$aOxford, [England] :$cOxford University Press,$d2010.
210  4$dİ2010
215   $a1 online resource (415 p.)
225 1 $aOxford Master Series in Physics
300   $aDescription based upon print version of record.
311   $a0-19-957337-9 
311   $a0-19-957336-0 
320   $aIncludes bibliographical references and index.
327   $a""Contents""; ""1 Introduction""; ""1.1 Classification of optical processes""; ""1.2 Optical coefficients""; ""1.3 The complex refractive index and dielectric constant""; ""1.4 Optical materials""; ""1.4.1 Crystalline insulators and semiconductors""; ""1.4.2 Glasses""; ""1.4.3 Metals""; ""1.4.4 Molecular materials""; ""1.4.5 Doped glasses and insulators""; ""1.5 Characteristic optical physics in the solid state""; ""1.5.1 Crystal symmetry""; ""1.5.2 Electronic bands""; ""1.5.3 Vibronic bands""; ""1.5.4 The density of states""; ""1.5.5 Delocalized states and collective excitations""
327   $a""1.6 Microscopic models""""Chapter summary""; ""Further reading""; ""Exercises""; ""2 Classical propagation""; ""2.1 Propagation of light in a dense optical medium""; ""2.1.1 Atomic oscillators""; ""2.1.2 Vibrational oscillators""; ""2.1.3 Free electron oscillators""; ""2.2 The dipole oscillator model""; ""2.2.1 The Lorentz oscillator""; ""2.2.2 Multiple resonances""; ""2.2.3 Comparison with experimental data""; ""2.2.4 Local field corrections""; ""2.3 The Kramersa???Kronig relationships""; ""2.4 Dispersion""; ""2.5 Optical anisotropy""; ""2.5.1 Natural anisotropy: birefringence""
327   $a""2.5.2 Induced optical anisotropy""""2.6 Optical chirality""; ""Chapter summary""; ""Further reading""; ""Exercises""; ""3 Interband absorption""; ""3.1 Interband transitions""; ""3.2 The transition rate for direct absorption""; ""3.3 Band edge absorption in direct gap semiconductors""; ""3.3.1 The atomic physics of the interband transitions""; ""3.3.2 The band structure of a direct gap IIIa???V semiconductor""; ""3.3.3 The joint density of states""; ""3.3.4 The frequency dependence of the band edge absorption""; ""3.3.5 The Franza???Keldysh effect""
327   $a""3.3.6 Band edge absorption in a magnetic field""""3.3.7 Spin injection""; ""3.4 Band edge absorption in indirect gap semiconductors""; ""3.5 Interband absorption above the band edge""; ""3.6 Measurement of absorption spectra""; ""3.7 Semiconductor photodetectors""; ""3.7.1 Photodiodes""; ""3.7.2 Photoconductive devices""; ""3.7.3 Photovoltaic devices""; ""Chapter summary""; ""Further reading""; ""Exercises""; ""4 Excitons""; ""4.1 The concept of excitons""; ""4.2 Free excitons""; ""4.2.1 Binding energy and radius""; ""4.2.2 Exciton absorption""
327   $a""4.2.3 Experimental data for free excitons in GaAs""""4.3 Free excitons in external fields""; ""4.3.1 Electric fields""; ""4.3.2 Magnetic fields""; ""4.4 Free excitons at high densities""; ""4.5 Frenkel excitons""; ""4.5.1 Rare gas crystals""; ""4.5.2 Alkali halides""; ""4.5.3 Molecular crystals""; ""Chapter summary""; ""Further reading""; ""Exercises""; ""5 Luminescence""; ""5.1 Light emission in solids""; ""5.2 Interband luminescence""; ""5.2.1 Direct gap materials""; ""5.2.2 Indirect gap materials""; ""5.3 Photoluminescence""; ""5.3.1 Excitation and relaxation""
327   $a""5.3.2 Low carrier densities""
410  0$aOxford master series in condensed matter physics.
606   $aSolids$xOptical properties
608   $aElectronic books.
615  0$aSolids$xOptical properties.
676   $a530.4/12
700   $aFox$b Mark$066654
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200 00$aHost-guest-systems based on nanoporous crystals$b[electronic resource] /$fFranco Laeri ... [et al.] (eds.)
210   $aWeinheim $cWiley-VCH$dc2003
215   $a1 online resource (688 p.)
300   $aDescription based upon print version of record.
311   $a3-527-30501-7 
320   $aIncludes bibliographical references and index.
327   $aHost-Guest-Systems Based on Nanoporous Crystals; Contents; List of Contributors; Part 1 Synthesis Routes for Functional Composites Based on Nanoporous Materials; References; 1 Guest Functionalized Crystalline Organic/Inorganic Nanohybrid Materials; 1.1 Introduction; 1.2 Direct Construction of Functional Host-Guest Compounds: Synthesis Between Scylla and Charybdis; 1.3 Stable Functional Structure-Directing Agents in the Synthesis of Porosils; 1.4 The Glycol Method for the Fast Synthesis of Aluminophosphates and the Occlusion of Organic Dye Molecules
327   $a1.5 Easily Crystallizing Inorganic Frameworks: Zincophosphates1.6 Conclusions; Acknowledgments; References; 2 In Situ Synthesis of Azo Dyes and Spiropyran Dyes in Faujasites and their Photochromic Properties; 2.1 Introduction; 2.2 In Situ Synthesis of Azo Dyes in Faujasites; 2.3 In Situ Synthesis of Spiropyran Dyes in Faujasites; 2.4 Optical Switching of Azo and a Spiropyran Dyes in Molecular Sieves; 2.5 Conclusions; Acknowledgments; References; 3 Microwave-Assisted Crystallization Inclusion of Dyes in Microporous AlPO(4)-5 and Mesoporous Si-MCM-41 Molecular Sieves; 3.1 Introduction
327   $a3.2 Dyes in the Microporous Molecular Sieve AlPO(4)-53.2.1 Crystallization Inclusion of Dyes in AlPO(4)-5; 3.2.2 Crystal Morphology of AlPO(4)-5; 3.3 Dyes in the Mesoporous Molecular Sieve Si-MCM-41; 3.4 Outlook; Acknowledgements; References; 4 Large and Perfect, Optically Transparent Crystals of an Unusual Habitus; 4.1 Introduction; 4.1.1 Synthesis of Molecular Sieve Crystals of Tailored Dimensions and Habitus; 4.2 Results and Discussion; 4.2.1 General Remarks and Synthesis Procedure; 4.2.2 Inorganic Acids and Salts of Alkaline Metals as Additional Components
327   $a4.2.3 Inorganic Salts of 2+ and Higher Valence Metal Ions as Additional Components4.2.4 Other Organic Templates as Additional Components and/or Co-Templates; 4.2.5 Organic Acids as Additional Components and Co-Templates; 4.2.6 Alcohols as Additional Components and Co-Templates; 4.2.7 Mixed Organic/Inorganic Additional Components as Co-Templates; 4.2.8 Aluminum Source as Directing Agent; 4.2.9 Preparation of the Reaction Gel as a Control Tool; 4.2.10 Sorption Characteristics of the Tailored Crystals; 4.3 Conclusions; Acknowledgements; References
327   $a5 Nanoporous Crystals as Host Matrices for Mesomorphous Phases5.1 Introduction; 5.2 Liquid Crystals Confined in Molecular Sieves; 5.3 Methods of Loading Molecular Sieves with Liquid Crystals; 5.4 Nanoporous Composites Based on Different Molecular Sieves; 5.4.1 MFI Type Molecular Sieves; 5.4.2 Faujasite; 5.4.3 Cloverite; 5.4.4 MCM-41 Molecular Sieves; 5.4.5 SBA-15 Materials; 5.4.6 Exchanged Nanoporous Materials; 5.5 On the Location of Liquid Crystals Inside the Pores or Cavities of Molecular Sieves; 5.6 Conclusions; Acknowledgements; References
327   $a6 Cationic Host-Guest Polymerization of Vinyl Monomers in MCM-41
330   $aInterest in nanoporous crystals as host-guest systems has risen dramatically over the past few years, such that this fascinating class of substances now plays an important role not only in material sciences, but also in numerous other disciplines, such as organic or supramolecular chemistry. With their unique characteristics, nanoporous crystals offer a wide range of possible applications: They are used as molecular sieves or membranes as well as catalytic converters. This work presents the very first overview of this exciting field.Readers will find everything they need to know about thes
606   $aNanostructured materials
606   $aPorous materials
606   $aMolecular sieves
608   $aElectronic books.
615  0$aNanostructured materials.
615  0$aPorous materials.
615  0$aMolecular sieves.
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