Optical properties of condensed matter and applications:
Gespeichert in:
| Format: | Buch |
|---|---|
| Sprache: | English |
| Veröffentlicht: |
Chichester
Wiley
2007
|
| Ausgabe: | Repr. |
| Schriftenreihe: | Wiley series in materials for electronic and optoelectronic applications
|
| Schlagworte: | |
| Online-Zugang: | Table of contents only Inhaltsverzeichnis |
| Beschreibung: | XIV, 434 S. graph. Darst. |
| ISBN: | 0470021926 9780470021927 |
Internformat
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| 245 | 1 | 0 | |a Optical properties of condensed matter and applications |c ed. by Jai Singh |
| 250 | |a Repr. | ||
| 264 | 1 | |a Chichester |b Wiley |c 2007 | |
| 300 | |a XIV, 434 S. |b graph. Darst. | ||
| 336 | |b txt |2 rdacontent | ||
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| 490 | 0 | |a Wiley series in materials for electronic and optoelectronic applications | |
| 650 | 4 | |a Condensed matter |x Optical properties | |
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Datensatz im Suchindex
| _version_ | 1804135774372757504 |
|---|---|
| adam_text | Contents
Series Preface xi
Preface xiii
1 Fundamental Optical Properties of Materials I 1
W.C. Tan, K. Koughia, J. Singh, and S.O. Kasap
1.1 Introduction 1
1.2 Optical Constants 2
1.2.1 Refractive index and extinction coefficient 2
1.2.2 n and K, and Kramers-Kronig relations 5
1.3 Refractive Index and Dispersion 6
1.3.1 Cauchy dispersion relation 7
1.3.2 Sellmeier dispersion equation 7
1.3.3 Refractive index of semiconductors 10
1.3.4 Gladstone-Dale formula and oxide glasses 12
1.3.5 Wemple-DiDomenico dispersion relation 12
1.3.6 Group index 14
1.4 The Swanepoel Technique: Measurement of n and a 14
1.4.1 Uniform-thickness films 14
1.4.2 Thin films with nonuniform thickness 19
1.5 Conclusions 23
2 Fundamental Optical Properties of Materials II 27
K. Koughia, J. Singh, S.O. Kasap, and H.E. Ruda
2.1 Introduction 27
2.2 Lattice or Reststrahlen Absorption and Infrared Reflection 30
2.3 Free-Carrier Absorption (FCA) 31
2.4 Band-to-Band or Fundamental Absorption (Crystalline Solids) 34
2.5 Impurity Absorption 38
2.5.1 Optical absorption of trivalent rare earth ions: Judd-Ofelt analysis 38
2.5.2 Optical absorption cross-section 41
2.6 Effect of External Fields 41
2.6.1 Electro-optic effects 41
2.6.2 Electro-absorption and Franz-Keldysh effect 42
2.6.3 Faraday effect 44
2.7 Conclusions 45
vi CONTENTS
3 Optical Properties of Disordered Condensed Matter 47
K. Shimakawa, J. Singh, and S.K. O Leary
3.1 Introduction 47
3.2 Fundamental Optical Absorption (Experimental) 49
3.2.1 Amorphous chalcogenides 49
3.2.2 Hydrogenated nanocrystalline silicon (nc-Si:H) 53
3.3 Absorption Coefficient (Theory) 54
3.4 Compositional Variation of the Optical Bandgap in Amorphous
Chalcogenides 60
3.5 Conclusions 61
4 Concept of Excitons 63
J. Singh and H.E. Ruda
4.1 Introduction 63
4.2 Excitons in Crystalline Solids 64
4.2.1 Excitonic absorption in crystalline solids 67
4.3 Excitons in Amorphous Semiconductors 69
4.3.1 Excitonic absorption in amorphous solids 71
4.4 Conclusions 73
5 Photoluminescence 75
T. Aoki
5.1 Introduction 75
5.2 Fundamental Aspects of Photoluminescence (PL) in Condensed Matter 76
5.3 Experimental Aspects 80
5.3.1 Static PL spectroscopy 80
5.3.2 Photoluminescence excitation spectroscopy (PLES) and
photoluminescence absorption spectroscopy (PLAS) 82
5.3.3 Time-resolved spectroscopy (TRS) 83
5.3.4 Time-correlated single-photon counting (TCSPC) 86
5.3.5 Frequency-resolved spectroscopy (FRS) 87
5.3.6 Quadrature frequency-resolved spectroscopy (QFRS) 88
5.4 Photoluminescence Lifetime Spectroscopy of Amorphous
Semiconductors by QFRS Technique 90
5.4.1 Overview 90
5.4.2 Dual-phase double lock-in (DPDL) QFRS technique 92
5.4.3 Exploring broad PL lifetime distribution in a-Si:H and a-Ge:H
by wideband QFRS 95
5.4.4 Residual PL decay of a-Si:H 102
5.5 Conclusions 103
6 Photoluminescence and Photoinduced Changes in Noncrystalline
Condensed Matter 107
/. Singh
6.1 Introduction 107
6.2 Photoluminescence 109
CONTENTS vii
6.2.1 Radiative recombination operator and transition matrix element 110
6.2.2 Rates of spontaneous emission 115
6.2.3 Results of spontaneous emission and radiative lifetime 121
6.2.4 Temperature dependence of PL 128
6.2.5 Excitonic concept 130
6.3 Photoinduced Changes in Amorphous Chalcogenides 131
6.3.1 Effect of photo-excitation and phonon interaction 132
6.3.2 Excitation of a single electron - hole pair 134
6.3.3 Pairing of like excited charge carriers 135
6.4 Conclusions 138
7 Light-induced Volume Changes in Chalcogenide Glasses 143
S. Kugler, J. Hegedus, and K. Kohary
7.1 Introduction 143
7.2 Simulation Method 145
7.3 Sample Preparation 146
7.4 Light Induced Phenomena 150
7.4.1 Electron excitation 150
7.4.2 Hole creation 151
7.5 Macroscopic Models 153
7.5.1 Ideal, reversible case (a-Se) 153
7.5.2 Non-ideal, irreversible case (a-As2Se3) 155
7.6 Conclusions 157
8 Optical Properties of Glasses 159
A. Edgar
8.1 Introduction 160
8.2 The Refractive Index 160
8.3 Glass Interfaces 162
8.4 Dispersion 165
8.5 Sensitivity of the Refractive Index 167
8.5.1 Temperature dependence 167
8.5.2 Stress dependence 168
8.5.3 Magnetic field dependence - the Faraday effect 168
8.5.4 Chemical perturbations - molar refractivity 171
8.6 Glass Color 171
8.6.1 Coloration by colloidal metals and semiconductors 172
8.6.2 Optical absorption in rare-earth-doped glass 173
8.6.3 Absorption by 3d metal ions 176
8.7 Fluorescence in Rare-earth-doped Glass 178
8.8 Glasses for Fibre Optics 181
8.9 Refractive Index Engineering 183
8.10 Transparent Glass Ceramics 185
8.10.1 Introduction 185
8.10.2 Theoretical basis for transparency 187
8.10.3 Rare-earth doped transparent glass ceramics for active photonics 190
viii CONTENTS
8.10.4 Ferroelectric transparent glass ceramics 192
8.10.5 Transparent glass ceramics for X-ray storage phosphors 192
8.11 Conclusions 194
9 Properties and Applications of Photonic Crystals 197
H.E. Ruda and N. Matsuura
9.1 Introduction 198
9.2 PC Overview 198
9.2.1 Introduction to PCs 200
9.2.2 Nano-engineering of PC architectures 202
9.2.3 Materials selection for PCs 203
9.3 Tunable PCs 203
9.3.1 Tuning PC response by changing the refractive index of
constituent materials 205
9.3.2 Tuning PC response by altering the physical structure of the PC 208
9.4 Selected Applications of PC 209
9.4.1 Waveguide devices 210
9.4.2 Dispersive devices 210
9.4.3 Add/Drop multiplexing devices 211
9.4.4 Applications of PCs for LEDs and lasers 212
9.5 Conclusions 213
10 Nonlinear Optical Properties of Photonic Glasses 215
K. Tanaka
10.1 Introduction 215
10.2 Photonic Glass 217
10.3 Nonlinear Absorption and Refractivity 219
10.3.1 Fundamentals 219
10.3.2 Two-photon absorption 222
10.3.3 Nonlinear refractivity 224
10.4 Nonlinear Excitation-Induced Structural Changes 226
10.4.1 Fundamentals 226
10.4.2 Oxides 227
10.4.3 Chalcogenides 229
10.5 Conclusions 231
11 Optical Properties of Organic Semiconductors and Applications 235
T. Kobayashi and H. Naito
11.1 Introduction 235
11.2 Molecular Structure of rc-Conjugated Polymers 236
11.3 Theoretical Models 237
11.4 Absorption Spectrum 240
11.5 Photoluminescence 243
11.6 Nonemissive Excited States 247
11.7 Electron-Electron Interaction 249
11.8 Interchain Interaction 254
11.9 Conclusions 258
CONTENTS ix
12 Organic Semiconductors and Applications 261
F.Zhu
12.1 Introduction 262
12.1.1 OLED architecture and operation principle 265
12.1.2 Technical challenges and process integration 265
12.2 Anode Modification for Enhanced OLED Performance 266
12.2.1 Low-temperature high-performance ITO 277
12.2.2 Anode modification 279
12.2.3 Electroluminescence performance of OLED 284
12.3 Flexible OLED Displays 284
12.3.1 Flexible OLEDs on ultra-thin glass substrate 286
12.3.2 Flexible top-emitting OLEDs on plastic foils 293
12.4 Conclusions 293
13 Optical Properties of Thin Films 297
V.V. Truong and S. Tanemura
13.1 Introduction 298
13.2 Optics of thin films 298
13.2.1 An isotropic film on a substrate 298
13.2.2 Matrix methods for multi-layered structures 300
13.2.3 Anisotropic films 302
13.3 Reflection-Transmission Photoellipsometry for Optical-Constants
Determination 303
13.3.1 Photoellipsometry of a thick or a thin film 303
13.3.2 Photoellipsometry for a stack of thick and thin films 306
13.3.3 Remarks on the reflection-transmission photoellipsometry
method 308
13.4 Applications of Thin Films to Energy Management and Renewable
Energy Technologies 309
13.4.1 Electrochromic thin films 309
13.4.2 Pure and metal-doped VO2 thermochromic thin films 310
13.4.3 Temperature-stabilized V,_VWVO2 sky radiator films 312
13.4.4 Optical functional TiO2 thin film for environmentally friendly
technologies 315
13.5 Conclusions 320
14 Negative Index of Refraction: Optics and Metamaterials 325
J.E. Kielbasa, D.L. Carroll and R.T. Williams
14.1 Introduction 326
14.1.1 Electric and magnetic response 329
14.1.2 Veselago s slab lens and Pendry s perfect lens 332
14.2 Optics of Propagating Waves with Negative Index 332
14.2.1 Foundation in Fourier optics 333
14.2.2 Fermat s principle in a slab lens 336
14.2.3 Ray tracing with negative index and aberrations 338
14.3 Super-resolution with the Slab Lens 338
14.3.1 Amplification of the evanescent waves 345
x CONTENTS
14.3.2 Aberrations in the evanescent image 345
14.3.3 Experimental results with evanescent waves 346
14.4 Negative Refraction with Metamaterials 348
14.5 Conclusions 352
15 Excitonic Processes in Quantum Wells 355
/. Singh and I.-K. Oh
15.1 Introduction 355
15.2 Exciton-Phonon Interaction 356
15.3 Exciton Formation in Quantum Wells Assisted by Phonons 357
15.4 Nonradiative Relaxation of Free Excitons 365
15.4.1 Intraband processes 365
15.4.2 Interband processes 370
15.5 Quasi-2D Free-Exciton Linewidth 376
15.6 Localization of Free Excitons 382
15.7 Conclusions 390
16 Optical Properties and Spin Dynamics of Diluted Magnetic
Semiconductor Nanostructures 393
A. Murayama and Y. Oka
16.1 Introduction 393
16.2 Coupled Quantum Wells 395
16.2.1 Spin injection 395
16.2.2 Spin separation and switching 397
16.2.3 Spin dynamics studied by pump-probe spectroscopy 400
16.3 Nanostructures Fabricated by Electron-Beam Lithography 403
16.4 Self-assembled Quantum Dots 407
16.5 Hybrid Nanostructures with Ferromagnetic Materials 410
16.6 Conclusions 413
Index 417
|
| adam_txt |
Contents
Series Preface xi
Preface xiii
1 Fundamental Optical Properties of Materials I 1
W.C. Tan, K. Koughia, J. Singh, and S.O. Kasap
1.1 Introduction 1
1.2 Optical Constants 2
1.2.1 Refractive index and extinction coefficient 2
1.2.2 n and K, and Kramers-Kronig relations 5
1.3 Refractive Index and Dispersion 6
1.3.1 Cauchy dispersion relation 7
1.3.2 Sellmeier dispersion equation 7
1.3.3 Refractive index of semiconductors 10
1.3.4 Gladstone-Dale formula and oxide glasses 12
1.3.5 Wemple-DiDomenico dispersion relation 12
1.3.6 Group index 14
1.4 The Swanepoel Technique: Measurement of n and a 14
1.4.1 Uniform-thickness films 14
1.4.2 Thin films with nonuniform thickness 19
1.5 Conclusions 23
2 Fundamental Optical Properties of Materials II 27
K. Koughia, J. Singh, S.O. Kasap, and H.E. Ruda
2.1 Introduction 27
2.2 Lattice or Reststrahlen Absorption and Infrared Reflection 30
2.3 Free-Carrier Absorption (FCA) 31
2.4 Band-to-Band or Fundamental Absorption (Crystalline Solids) 34
2.5 Impurity Absorption 38
2.5.1 Optical absorption of trivalent rare earth ions: Judd-Ofelt analysis 38
2.5.2 Optical absorption cross-section 41
2.6 Effect of External Fields 41
2.6.1 Electro-optic effects 41
2.6.2 Electro-absorption and Franz-Keldysh effect 42
2.6.3 Faraday effect 44
2.7 Conclusions 45
vi CONTENTS
3 Optical Properties of Disordered Condensed Matter 47
K. Shimakawa, J. Singh, and S.K. O'Leary
3.1 Introduction 47
3.2 Fundamental Optical Absorption (Experimental) 49
3.2.1 Amorphous chalcogenides 49
3.2.2 Hydrogenated nanocrystalline silicon (nc-Si:H) 53
3.3 Absorption Coefficient (Theory) 54
3.4 Compositional Variation of the Optical Bandgap in Amorphous
Chalcogenides 60
3.5 Conclusions 61
4 Concept of Excitons 63
J. Singh and H.E. Ruda
4.1 Introduction 63
4.2 Excitons in Crystalline Solids 64
4.2.1 Excitonic absorption in crystalline solids 67
4.3 Excitons in Amorphous Semiconductors 69
4.3.1 Excitonic absorption in amorphous solids 71
4.4 Conclusions 73
5 Photoluminescence 75
T. Aoki
5.1 Introduction 75
5.2 Fundamental Aspects of Photoluminescence (PL) in Condensed Matter 76
5.3 Experimental Aspects 80
5.3.1 Static PL spectroscopy 80
5.3.2 Photoluminescence excitation spectroscopy (PLES) and
photoluminescence absorption spectroscopy (PLAS) 82
5.3.3 Time-resolved spectroscopy (TRS) 83
5.3.4 Time-correlated single-photon counting (TCSPC) 86
5.3.5 Frequency-resolved spectroscopy (FRS) 87
5.3.6 Quadrature frequency-resolved spectroscopy (QFRS) 88
5.4 Photoluminescence Lifetime Spectroscopy of Amorphous
Semiconductors by QFRS Technique 90
5.4.1 Overview 90
5.4.2 Dual-phase double lock-in (DPDL) QFRS technique 92
5.4.3 Exploring broad PL lifetime distribution in a-Si:H and a-Ge:H
by wideband QFRS 95
5.4.4 Residual PL decay of a-Si:H 102
5.5 Conclusions 103
6 Photoluminescence and Photoinduced Changes in Noncrystalline
Condensed Matter 107
/. Singh
6.1 Introduction 107
6.2 Photoluminescence 109
CONTENTS vii
6.2.1 Radiative recombination operator and transition matrix element 110
6.2.2 Rates of spontaneous emission 115
6.2.3 Results of spontaneous emission and radiative lifetime 121
6.2.4 Temperature dependence of PL 128
6.2.5 Excitonic concept 130
6.3 Photoinduced Changes in Amorphous Chalcogenides 131
6.3.1 Effect of photo-excitation and phonon interaction 132
6.3.2 Excitation of a single electron - hole pair 134
6.3.3 Pairing of like excited charge carriers 135
6.4 Conclusions 138
7 Light-induced Volume Changes in Chalcogenide Glasses 143
S. Kugler, J. Hegedus, and K. Kohary
7.1 Introduction 143
7.2 Simulation Method 145
7.3 Sample Preparation 146
7.4 Light Induced Phenomena 150
7.4.1 Electron excitation 150
7.4.2 Hole creation 151
7.5 Macroscopic Models 153
7.5.1 Ideal, reversible case (a-Se) 153
7.5.2 Non-ideal, irreversible case (a-As2Se3) 155
7.6 Conclusions 157
8 Optical Properties of Glasses 159
A. Edgar
8.1 Introduction 160
8.2 The Refractive Index 160
8.3 Glass Interfaces 162
8.4 Dispersion 165
8.5 Sensitivity of the Refractive Index 167
8.5.1 Temperature dependence 167
8.5.2 Stress dependence 168
8.5.3 Magnetic field dependence - the Faraday effect 168
8.5.4 Chemical perturbations - molar refractivity 171
8.6 Glass Color 171
8.6.1 Coloration by colloidal metals and semiconductors 172
8.6.2 Optical absorption in rare-earth-doped glass 173
8.6.3 Absorption by 3d metal ions 176
8.7 Fluorescence in Rare-earth-doped Glass 178
8.8 Glasses for Fibre Optics 181
8.9 Refractive Index Engineering 183
8.10 Transparent Glass Ceramics 185
8.10.1 Introduction 185
8.10.2 Theoretical basis for transparency 187
8.10.3 Rare-earth doped transparent glass ceramics for active photonics 190
viii CONTENTS
8.10.4 Ferroelectric transparent glass ceramics 192
8.10.5 Transparent glass ceramics for X-ray storage phosphors 192
8.11 Conclusions 194
9 Properties and Applications of Photonic Crystals 197
H.E. Ruda and N. Matsuura
9.1 Introduction 198
9.2 PC Overview 198
9.2.1 Introduction to PCs 200
9.2.2 Nano-engineering of PC architectures 202
9.2.3 Materials selection for PCs 203
9.3 Tunable PCs 203
9.3.1 Tuning PC response by changing the refractive index of
constituent materials 205
9.3.2 Tuning PC response by altering the physical structure of the PC 208
9.4 Selected Applications of PC 209
9.4.1 Waveguide devices 210
9.4.2 Dispersive devices 210
9.4.3 Add/Drop multiplexing devices 211
9.4.4 Applications of PCs for LEDs and lasers 212
9.5 Conclusions 213
10 Nonlinear Optical Properties of Photonic Glasses 215
K. Tanaka
10.1 Introduction 215
10.2 Photonic Glass 217
10.3 Nonlinear Absorption and Refractivity 219
10.3.1 Fundamentals 219
10.3.2 Two-photon absorption 222
10.3.3 Nonlinear refractivity 224
10.4 Nonlinear Excitation-Induced Structural Changes 226
10.4.1 Fundamentals 226
10.4.2 Oxides 227
10.4.3 Chalcogenides 229
10.5 Conclusions 231
11 Optical Properties of Organic Semiconductors and Applications 235
T. Kobayashi and H. Naito
11.1 Introduction 235
11.2 Molecular Structure of rc-Conjugated Polymers 236
11.3 Theoretical Models 237
11.4 Absorption Spectrum 240
11.5 Photoluminescence 243
11.6 Nonemissive Excited States 247
11.7 Electron-Electron Interaction 249
11.8 Interchain Interaction 254
11.9 Conclusions 258
CONTENTS ix
12 Organic Semiconductors and Applications 261
F.Zhu
12.1 Introduction 262
12.1.1 OLED architecture and operation principle 265
12.1.2 Technical challenges and process integration 265
12.2 Anode Modification for Enhanced OLED Performance 266
12.2.1 Low-temperature high-performance ITO 277
12.2.2 Anode modification 279
12.2.3 Electroluminescence performance of OLED 284
12.3 Flexible OLED Displays 284
12.3.1 Flexible OLEDs on ultra-thin glass substrate 286
12.3.2 Flexible top-emitting OLEDs on plastic foils 293
12.4 Conclusions 293
13 Optical Properties of Thin Films 297
V.V. Truong and S. Tanemura
13.1 Introduction 298
13.2 Optics of thin films 298
13.2.1 An isotropic film on a substrate 298
13.2.2 Matrix methods for multi-layered structures 300
13.2.3 Anisotropic films 302
13.3 Reflection-Transmission Photoellipsometry for Optical-Constants
Determination 303
13.3.1 Photoellipsometry of a thick or a thin film 303
13.3.2 Photoellipsometry for a stack of thick and thin films 306
13.3.3 Remarks on the reflection-transmission photoellipsometry
method 308
13.4 Applications of Thin Films to Energy Management and Renewable
Energy Technologies 309
13.4.1 Electrochromic thin films 309
13.4.2 Pure and metal-doped VO2 thermochromic thin films 310
13.4.3 Temperature-stabilized V,_VWVO2 sky radiator films 312
13.4.4 Optical functional TiO2 thin film for environmentally friendly
technologies 315
13.5 Conclusions 320
14 Negative Index of Refraction: Optics and Metamaterials 325
J.E. Kielbasa, D.L. Carroll and R.T. Williams
14.1 Introduction 326
14.1.1 Electric and magnetic response 329
14.1.2 Veselago's slab lens and Pendry's perfect lens 332
14.2 Optics of Propagating Waves with Negative Index 332
14.2.1 Foundation in Fourier optics 333
14.2.2 Fermat's principle in a slab lens 336
14.2.3 Ray tracing with negative index and aberrations 338
14.3 Super-resolution with the Slab Lens 338
14.3.1 Amplification of the evanescent waves 345
x CONTENTS
14.3.2 Aberrations in the evanescent image 345
14.3.3 Experimental results with evanescent waves 346
14.4 Negative Refraction with Metamaterials 348
14.5 Conclusions 352
15 Excitonic Processes in Quantum Wells 355
/. Singh and I.-K. Oh
15.1 Introduction 355
15.2 Exciton-Phonon Interaction 356
15.3 Exciton Formation in Quantum Wells Assisted by Phonons 357
15.4 Nonradiative Relaxation of Free Excitons 365
15.4.1 Intraband processes 365
15.4.2 Interband processes 370
15.5 Quasi-2D Free-Exciton Linewidth 376
15.6 Localization of Free Excitons 382
15.7 Conclusions 390
16 Optical Properties and Spin Dynamics of Diluted Magnetic
Semiconductor Nanostructures 393
A. Murayama and Y. Oka
16.1 Introduction 393
16.2 Coupled Quantum Wells 395
16.2.1 Spin injection 395
16.2.2 Spin separation and switching 397
16.2.3 Spin dynamics studied by pump-probe spectroscopy 400
16.3 Nanostructures Fabricated by Electron-Beam Lithography 403
16.4 Self-assembled Quantum Dots 407
16.5 Hybrid Nanostructures with Ferromagnetic Materials 410
16.6 Conclusions 413
Index 417 |
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| genre | (DE-588)4143413-4 Aufsatzsammlung gnd-content |
| genre_facet | Aufsatzsammlung |
| id | DE-604.BV021840256 |
| illustrated | Illustrated |
| index_date | 2024-07-02T16:00:12Z |
| indexdate | 2024-07-09T20:45:51Z |
| institution | BVB |
| isbn | 0470021926 9780470021927 |
| language | English |
| lccn | 2006014789 |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-015052124 |
| oclc_num | 633597294 |
| open_access_boolean | |
| owner | DE-703 DE-29T DE-11 |
| owner_facet | DE-703 DE-29T DE-11 |
| physical | XIV, 434 S. graph. Darst. |
| publishDate | 2007 |
| publishDateSearch | 2007 |
| publishDateSort | 2007 |
| publisher | Wiley |
| record_format | marc |
| series2 | Wiley series in materials for electronic and optoelectronic applications |
| spelling | Optical properties of condensed matter and applications ed. by Jai Singh Repr. Chichester Wiley 2007 XIV, 434 S. graph. Darst. txt rdacontent n rdamedia nc rdacarrier Wiley series in materials for electronic and optoelectronic applications Condensed matter Optical properties Festkörper (DE-588)4016918-2 gnd rswk-swf Optische Eigenschaft (DE-588)4123887-4 gnd rswk-swf (DE-588)4143413-4 Aufsatzsammlung gnd-content Festkörper (DE-588)4016918-2 s Optische Eigenschaft (DE-588)4123887-4 s DE-604 Singh, Jai Sonstige oth http://www.loc.gov/catdir/toc/ecip0613/2006014789.html Table of contents only HBZ Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=015052124&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis |
| spellingShingle | Optical properties of condensed matter and applications Condensed matter Optical properties Festkörper (DE-588)4016918-2 gnd Optische Eigenschaft (DE-588)4123887-4 gnd |
| subject_GND | (DE-588)4016918-2 (DE-588)4123887-4 (DE-588)4143413-4 |
| title | Optical properties of condensed matter and applications |
| title_auth | Optical properties of condensed matter and applications |
| title_exact_search | Optical properties of condensed matter and applications |
| title_exact_search_txtP | Optical properties of condensed matter and applications |
| title_full | Optical properties of condensed matter and applications ed. by Jai Singh |
| title_fullStr | Optical properties of condensed matter and applications ed. by Jai Singh |
| title_full_unstemmed | Optical properties of condensed matter and applications ed. by Jai Singh |
| title_short | Optical properties of condensed matter and applications |
| title_sort | optical properties of condensed matter and applications |
| topic | Condensed matter Optical properties Festkörper (DE-588)4016918-2 gnd Optische Eigenschaft (DE-588)4123887-4 gnd |
| topic_facet | Condensed matter Optical properties Festkörper Optische Eigenschaft Aufsatzsammlung |
| url | http://www.loc.gov/catdir/toc/ecip0613/2006014789.html http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=015052124&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA |
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