Wave optics in infrared spectroscopy theory, simulation, and modeling
Intro -- Wave Optics in Infrared Spectroscopy: Theory, Simulation, and Modeling -- Copyright -- Dedication -- Contents -- Foreword -- Preface -- Part I: Scalar theory -- Chapter 1: What is wrong with absorbance? -- References -- Chapter 2: Transition from the Bouguer-Beer-Lambert approximation to wa...
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| Format: | UnknownFormat |
| Sprache: | eng |
| Veröffentlicht: |
Amsterdam, London, Cambridge, MA
Elsevier
2024
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| Online Zugang: | Inhaltsverzeichnis |
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Tag hinzufügen | Zusammenfassung: | Intro -- Wave Optics in Infrared Spectroscopy: Theory, Simulation, and Modeling -- Copyright -- Dedication -- Contents -- Foreword -- Preface -- Part I: Scalar theory -- Chapter 1: What is wrong with absorbance? -- References -- Chapter 2: Transition from the Bouguer-Beer-Lambert approximation to wave optics and dispersion theory -- 2.1. The electric field and the electric displacement -- 2.2. The magnetic field and the magnetic induction -- 2.3. Maxwells equations in simplified form -- 2.3.1. 1st equation-Gausss law -- 2.3.2. 2nd equation-Faradays law of induction 2.3.3. 3rd equation-Gausss law for magnetism -- 2.3.4. 4th equation-Amperes circuital law -- 2.4. Deriving the wave equation -- 2.5. One-dimensional and harmonic waves -- 2.6. Harmonic molecular vibrations and the dielectric function -- 2.7. The Kramers-Kronig relations -- 2.8. The influence of absorption on the electromagnetic waves -- 2.9. Reflection and transmission at an interface separating two scalar media under normal incidence -- 2.10. Transmission through a thick slab suspended in vacuum -- 2.11. Transmission through a thin slab suspended in vacuum 2.12. Transmission through a layer on a substrate suspended in vacuum -- 2.13. Scalar and vector fields -- 2.14. Further reading -- References -- Chapter 3: The electromagnetic field -- 3.1. Maxwells relations -- 3.2. Boundary conditions -- 3.3. Energy density and flux -- 3.4. The wave equation -- 3.5. Polarized waves -- 3.6. Further reading -- References -- Chapter 4: Reflection and transmission of plane waves -- 4.1. Reflection and transmission at an interface separating two scalar media under normal incidence 4.2. Reflection and transmission at an interface separating two scalar semiinfinite media under nonnormal incidence -- 4.2.1. s-Polarized light -- 4.2.2. p-Polarized light -- 4.2.3. Calculation of reflectance and transmittance -- 4.2.4. Example: Dependence of the reflectance from the angle of incidence -- 4.3. Reflection and transmission at an interface separating two scalar media under nonnormal incidence-absorbing media -- 4.4. Reflection and transmission at an interface separating two scalar media under nonnormal incidence-Total/internal ref ... 4.5. Reflection and transmission at an interface separating two scalar media under nonnormal incidence-Matrix formalism -- 4.5.1. Matrix formulation for s-polarized waves at a single interface -- 4.5.2. Matrix formulation for p-polarized waves at a single interface -- 4.5.3. Combined matrix formulation for waves at a single interface -- 4.5.4. A layer sandwiched by two semiinfinite media -- 4.5.5. Arbitrary number of layers -- 4.5.6. Calculating the electric field strengths of a layered medium-Coherent layers -- 4.5.7. Incoherent layers -- 4.5.8. Mixed coherent and incoherent layers |
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| Beschreibung: | Enthält Literaturangaben und Index |
| Beschreibung: | xiv, 386 Seiten Illustrationen, Diagramme |
| ISBN: | 9780443220319 978-0-443-22031-9 |