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Handbook of infrared spectroscopy of ultrathin films [[electronic resource] /] / Valeri P. Tolstoy, Irina V. Chernyshova, Valeri A. Skryshevsky
Handbook of infrared spectroscopy of ultrathin films [[electronic resource] /] / Valeri P. Tolstoy, Irina V. Chernyshova, Valeri A. Skryshevsky
Autore Tolstoy Valeri P
Pubbl/distr/stampa Hoboken, N.J., : Wiley-Interscience, c2003
Descrizione fisica 1 online resource (738 p.)
Disciplina 530.4175
621.38152
Altri autori (Persone) ChernyshovaIrina V
SkryshevskyValeri A
Soggetto topico Thin films - Optical properties
Infrared spectroscopy
Soggetto genere / forma Electronic books.
ISBN 1-280-36702-4
9786610367023
0-470-35236-1
0-471-46183-0
0-471-23432-X
Formato Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione eng
Nota di contenuto HANDBOOK OF INFRARED SPECTROSCOPY OF ULTRATHIN FILMS; CONTENTS; Preface; Acronyms and Symbols; Introduction; 1 Absorption and Reflection of Infrared Radiation by Ultrathin Films; 1.1. Macroscopic Theory of Propagation of Electromagnetic Waves in Infinite Medium; 1.2. Modeling Optical Properties of a Material; 1.3. Classical Dispersion Models of Absorption; 1.4. Propagation of IR Radiation through Planar Interface between Two Isotropic Media; 1.4.1. Transparent Media; 1.4.2. General Case; 1.5. Reflection of Radiation at Planar Interface Covered by Single Layer
1.6. Transmission of Layer Located at Interface between Two Isotropic Semi-infinite Media1.7. System of Plane-Parallel Layers: Matrix Method; 1.8. Energy Absorption in Layered Media; 1.8.1. External Reflection: Transparent Substrates; 1.8.2. External Reflection: Metallic Substrates; 1.8.3. ATR; 1.9. Effective Medium Theory; 1.10. Diffuse Reflection and Transmission; Appendix; References; 2 Optimum Conditions for Recording Infrared Spectra of Ultrathin Films; 2.1. IR Transmission Spectra Obtained in Polarized Radiation; 2.2. IRRAS Spectra of Layers on Metallic Surfaces ("Metallic" IRRAS)
2.3. IRRAS of Layers on Semiconductors and Dielectrics2.3.1. Transparent and Weakly Absorbing Substrates ("Transparent" IRRAS); 2.3.2. Absorbing Substrates; 2.3.3. Buried Metal Layer Substrates (BML-IRRAS); 2.4. ATR Spectra; 2.5. IR Spectra of Layers Located at Interface; 2.5.1. Transmission; 2.5.2. Metallic IRRAS; 2.5.3. Transparent IRRAS; 2.5.4. ATR; 2.6. Choosing Appropriate IR Spectroscopic Method for Layer on Flat Surface; 2.7. Coatings on Powders, Fibers, and Matte Surfaces; 2.7.1. Transmission; 2.7.2. Diffuse Transmittance and Diffuse Reflectance; 2.7.3. ATR
2.7.4. Comparison of IR Spectroscopic Methods for Studying Ultrathin Films on PowdersReferences; 3 Interpretation of IR Spectra of Ultrathin Films; 3.1. Dependence of Transmission, ATR, and IRRAS Spectra of Ultrathin Films on Polarization (Berreman Effect); 3.2. Theory of Berreman Effect; 3.2.1. Surface Modes; 3.2.2. Modes in Ultrathin Films; 3.2.3. Identification of Berreman Effect in IR Spectra of Ultrathin Films; 3.3. Optical Effect: Film Thickness, Angle of Incidence, and Immersion; 3.3.1. Effect in "Metallic" IRRAS; 3.3.2. Effect in "Transparent" IRRAS; 3.3.3. Effect in ATR Spectra
3.3.4. Effect in Transmission Spectra3.4. Optical Effect: Band Shapes in IRRAS as Function of Optical Properties of Substrate; 3.5. Optical Property Gradients at Substrate-Layer Interface: Effect on Band Intensities in IRRAS; 3.6. Dipole-Dipole Coupling; 3.7. Specific Features in Potential-Difference IR Spectra of Electrode-Electrolyte Interfaces; 3.7.1. Absorption Due to Bulk Electrolyte; 3.7.2. (Re)organization of Electrolyte in DL; 3.7.3. Donation/Backdonation of Electrons; 3.7.4. Stark Effect; 3.7.5. Bipolar Bands; 3.7.6. Effect of Coadsorption; 3.7.7. Electronic Absorption
3.7.8. Optical Effects
Record Nr. UNINA-9910143190303321
Tolstoy Valeri P  
Hoboken, N.J., : Wiley-Interscience, c2003
Materiale a stampa
Lo trovi qui: Univ. Federico II
Opac: Controlla la disponibilità qui
Handbook of infrared spectroscopy of ultrathin films [[electronic resource] /] / Valeri P. Tolstoy, Irina V. Chernyshova, Valeri A. Skryshevsky
Handbook of infrared spectroscopy of ultrathin films [[electronic resource] /] / Valeri P. Tolstoy, Irina V. Chernyshova, Valeri A. Skryshevsky
Autore Tolstoy Valeri P
Pubbl/distr/stampa Hoboken, N.J., : Wiley-Interscience, c2003
Descrizione fisica 1 online resource (738 p.)
Disciplina 530.4175
621.38152
Altri autori (Persone) ChernyshovaIrina V
SkryshevskyValeri A
Soggetto topico Thin films - Optical properties
Infrared spectroscopy
ISBN 1-280-36702-4
9786610367023
0-470-35236-1
0-471-46183-0
0-471-23432-X
Formato Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione eng
Nota di contenuto HANDBOOK OF INFRARED SPECTROSCOPY OF ULTRATHIN FILMS; CONTENTS; Preface; Acronyms and Symbols; Introduction; 1 Absorption and Reflection of Infrared Radiation by Ultrathin Films; 1.1. Macroscopic Theory of Propagation of Electromagnetic Waves in Infinite Medium; 1.2. Modeling Optical Properties of a Material; 1.3. Classical Dispersion Models of Absorption; 1.4. Propagation of IR Radiation through Planar Interface between Two Isotropic Media; 1.4.1. Transparent Media; 1.4.2. General Case; 1.5. Reflection of Radiation at Planar Interface Covered by Single Layer
1.6. Transmission of Layer Located at Interface between Two Isotropic Semi-infinite Media1.7. System of Plane-Parallel Layers: Matrix Method; 1.8. Energy Absorption in Layered Media; 1.8.1. External Reflection: Transparent Substrates; 1.8.2. External Reflection: Metallic Substrates; 1.8.3. ATR; 1.9. Effective Medium Theory; 1.10. Diffuse Reflection and Transmission; Appendix; References; 2 Optimum Conditions for Recording Infrared Spectra of Ultrathin Films; 2.1. IR Transmission Spectra Obtained in Polarized Radiation; 2.2. IRRAS Spectra of Layers on Metallic Surfaces ("Metallic" IRRAS)
2.3. IRRAS of Layers on Semiconductors and Dielectrics2.3.1. Transparent and Weakly Absorbing Substrates ("Transparent" IRRAS); 2.3.2. Absorbing Substrates; 2.3.3. Buried Metal Layer Substrates (BML-IRRAS); 2.4. ATR Spectra; 2.5. IR Spectra of Layers Located at Interface; 2.5.1. Transmission; 2.5.2. Metallic IRRAS; 2.5.3. Transparent IRRAS; 2.5.4. ATR; 2.6. Choosing Appropriate IR Spectroscopic Method for Layer on Flat Surface; 2.7. Coatings on Powders, Fibers, and Matte Surfaces; 2.7.1. Transmission; 2.7.2. Diffuse Transmittance and Diffuse Reflectance; 2.7.3. ATR
2.7.4. Comparison of IR Spectroscopic Methods for Studying Ultrathin Films on PowdersReferences; 3 Interpretation of IR Spectra of Ultrathin Films; 3.1. Dependence of Transmission, ATR, and IRRAS Spectra of Ultrathin Films on Polarization (Berreman Effect); 3.2. Theory of Berreman Effect; 3.2.1. Surface Modes; 3.2.2. Modes in Ultrathin Films; 3.2.3. Identification of Berreman Effect in IR Spectra of Ultrathin Films; 3.3. Optical Effect: Film Thickness, Angle of Incidence, and Immersion; 3.3.1. Effect in "Metallic" IRRAS; 3.3.2. Effect in "Transparent" IRRAS; 3.3.3. Effect in ATR Spectra
3.3.4. Effect in Transmission Spectra3.4. Optical Effect: Band Shapes in IRRAS as Function of Optical Properties of Substrate; 3.5. Optical Property Gradients at Substrate-Layer Interface: Effect on Band Intensities in IRRAS; 3.6. Dipole-Dipole Coupling; 3.7. Specific Features in Potential-Difference IR Spectra of Electrode-Electrolyte Interfaces; 3.7.1. Absorption Due to Bulk Electrolyte; 3.7.2. (Re)organization of Electrolyte in DL; 3.7.3. Donation/Backdonation of Electrons; 3.7.4. Stark Effect; 3.7.5. Bipolar Bands; 3.7.6. Effect of Coadsorption; 3.7.7. Electronic Absorption
3.7.8. Optical Effects
Record Nr. UNINA-9910829913703321
Tolstoy Valeri P  
Hoboken, N.J., : Wiley-Interscience, c2003
Materiale a stampa
Lo trovi qui: Univ. Federico II
Opac: Controlla la disponibilità qui
Handbook of infrared spectroscopy of ultrathin films / / Valeri P. Tolstoy, Irina V. Chernyshova, Valeri A. Skryshevsky
Handbook of infrared spectroscopy of ultrathin films / / Valeri P. Tolstoy, Irina V. Chernyshova, Valeri A. Skryshevsky
Autore Tolstoy Valeri P
Pubbl/distr/stampa Hoboken, N.J., : Wiley-Interscience, c2003
Descrizione fisica 1 online resource (738 p.)
Disciplina 621.3815/2
Altri autori (Persone) ChernyshovaIrina V
SkryshevskyValeri A
Soggetto topico Thin films - Optical properties
Infrared spectroscopy
ISBN 1-280-36702-4
9786610367023
0-470-35236-1
0-471-46183-0
0-471-23432-X
Formato Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione eng
Nota di contenuto HANDBOOK OF INFRARED SPECTROSCOPY OF ULTRATHIN FILMS; CONTENTS; Preface; Acronyms and Symbols; Introduction; 1 Absorption and Reflection of Infrared Radiation by Ultrathin Films; 1.1. Macroscopic Theory of Propagation of Electromagnetic Waves in Infinite Medium; 1.2. Modeling Optical Properties of a Material; 1.3. Classical Dispersion Models of Absorption; 1.4. Propagation of IR Radiation through Planar Interface between Two Isotropic Media; 1.4.1. Transparent Media; 1.4.2. General Case; 1.5. Reflection of Radiation at Planar Interface Covered by Single Layer
1.6. Transmission of Layer Located at Interface between Two Isotropic Semi-infinite Media1.7. System of Plane-Parallel Layers: Matrix Method; 1.8. Energy Absorption in Layered Media; 1.8.1. External Reflection: Transparent Substrates; 1.8.2. External Reflection: Metallic Substrates; 1.8.3. ATR; 1.9. Effective Medium Theory; 1.10. Diffuse Reflection and Transmission; Appendix; References; 2 Optimum Conditions for Recording Infrared Spectra of Ultrathin Films; 2.1. IR Transmission Spectra Obtained in Polarized Radiation; 2.2. IRRAS Spectra of Layers on Metallic Surfaces ("Metallic" IRRAS)
2.3. IRRAS of Layers on Semiconductors and Dielectrics2.3.1. Transparent and Weakly Absorbing Substrates ("Transparent" IRRAS); 2.3.2. Absorbing Substrates; 2.3.3. Buried Metal Layer Substrates (BML-IRRAS); 2.4. ATR Spectra; 2.5. IR Spectra of Layers Located at Interface; 2.5.1. Transmission; 2.5.2. Metallic IRRAS; 2.5.3. Transparent IRRAS; 2.5.4. ATR; 2.6. Choosing Appropriate IR Spectroscopic Method for Layer on Flat Surface; 2.7. Coatings on Powders, Fibers, and Matte Surfaces; 2.7.1. Transmission; 2.7.2. Diffuse Transmittance and Diffuse Reflectance; 2.7.3. ATR
2.7.4. Comparison of IR Spectroscopic Methods for Studying Ultrathin Films on PowdersReferences; 3 Interpretation of IR Spectra of Ultrathin Films; 3.1. Dependence of Transmission, ATR, and IRRAS Spectra of Ultrathin Films on Polarization (Berreman Effect); 3.2. Theory of Berreman Effect; 3.2.1. Surface Modes; 3.2.2. Modes in Ultrathin Films; 3.2.3. Identification of Berreman Effect in IR Spectra of Ultrathin Films; 3.3. Optical Effect: Film Thickness, Angle of Incidence, and Immersion; 3.3.1. Effect in "Metallic" IRRAS; 3.3.2. Effect in "Transparent" IRRAS; 3.3.3. Effect in ATR Spectra
3.3.4. Effect in Transmission Spectra3.4. Optical Effect: Band Shapes in IRRAS as Function of Optical Properties of Substrate; 3.5. Optical Property Gradients at Substrate-Layer Interface: Effect on Band Intensities in IRRAS; 3.6. Dipole-Dipole Coupling; 3.7. Specific Features in Potential-Difference IR Spectra of Electrode-Electrolyte Interfaces; 3.7.1. Absorption Due to Bulk Electrolyte; 3.7.2. (Re)organization of Electrolyte in DL; 3.7.3. Donation/Backdonation of Electrons; 3.7.4. Stark Effect; 3.7.5. Bipolar Bands; 3.7.6. Effect of Coadsorption; 3.7.7. Electronic Absorption
3.7.8. Optical Effects
Record Nr. UNINA-9910876899003321
Tolstoy Valeri P  
Hoboken, N.J., : Wiley-Interscience, c2003
Materiale a stampa
Lo trovi qui: Univ. Federico II
Opac: Controlla la disponibilità qui