| Description |
1 online resource (x, 225 pages) : illustrations |
| Contents |
Cover -- Preface -- Contents -- Chapter 1. Quantization of Energy -- 1.1 Introduction -- 1.2 Bohr Model of Hydrogen Atom -- 1.3 Idea of Wave-Particle Duality -- 1.4 Heisenberg Uncertainty Principle -- 1.5 Probability -- 1.6 Schrodinger Wave Equation -- 1.7 Significance of Wave Function, Ï? -- 1.8 Wave Equation for Hydrogen Atom -- 1.9 Spectra of Hydrogen Atoms -- 1.10 Use of Atomic Term Symbols to Describe Atomic Spectra -- 1.11 Wave Equations for Some Systems -- Chapter 2. Introduction to Molecular Spectroscopy -- 2.1 Spectroscopy |
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2.2 Nature of Radiation2.3 Born-Oppenheimer Approximation -- 2.4 Absorption, Emission and Scattering Spectra -- 2.5 Spectrophotometers -- 2.6 Regions of Electromagnetic Radiations -- 2.7 Intensity of Spectral Lines -- 2.8 Width of Spectral Lines -- 2.9 Scattering Spectra-Raman Spectroscopy -- 2.10 Importance of Molecular Spectroscopy -- Problems -- Chapter 3. Particle in a Box -- 3.1 Particle in One-Dimensional Box -- 3.2 Quantization of Energy -- 3.3 Zero Point Energy -- 3.4 Particle in a Three-Dimensional Cubical Box -- 3.5 Degeneracy |
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Chapter 4. Rotational Spectra4.1 Introduction -- 4.2 Diatomic Molecules as a Rigid Rotator and Energy Levels -- 4.3 Selection Rules -- 4.4 Effect of Isotopic Substitution -- 4.5 Intensity of Spectral Lines -- 4.6 Rotational Raman Spectrum -- Problems -- Problems -- Chapter 5. Vibrational Spectra -- 5.1 A Vibrating Diatomic Molecule -- 5.2 Selection Rules -- 5.3 Effect of Isotopic Substitution -- 5.4 Interaction Between IR-Radiation and Vibrating Molecules -- 5.5 Anharmonicity in Vibrations -- 5.6 Vibrational Raman Spectra -- 5.7 Polyatomic Molecules |
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5.8 Carbon Dioxide5.9 Water -- Problems -- Chapter 6. Group Frequency Concept -- 6.1 Introduction -- 6.2 Regions -- 6.3 Effect of Hydrogen Bonding -- 6.4 Application of IR Spectra in Structure Determination -- 6.5 Sample Preparation for Spectra Recording -- Problems -- Chapter 7. Electronic Spectra -- 7.1 Born-Oppenheimer Approximation -- 7.2 Electronic Transitions in Heteronuclear Diatomic Molecules -- 7.3 Homonuclear Diatomic Molecules -- 7.4 Franck-Condon Principle -- 7.5 Dissociation Energy -- 7.6 Dissociation Energy and Temperature |
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7.7 Dissipation of Energy by Excited Molecules 7.8 Phosphorescence -- Problems -- Chapter 8. Electronic Transitions in Organic Molecules -- 8.1 Various Bonds and Transitions -- 8.2 Some Important Terms Used in Electronic Transitions -- 8.3 Absorption Due to Ethylene Chromophore -- 8.4 Acetylenic and Benzenoid Chromophores -- 8.5 Carbonyl Chromophore -- 8.6 Solvent Effects on Electronic Spectra -- 8.7 Colour and Constitution -- 8.8 Sample Preparation -- Problems -- Chapter 9. Transition Metal Complexes and their Electronic Structures |
| Bibliography |
Includes bibliographical references and index |
| Notes |
English |
| Subject |
Molecular spectroscopy.
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Molecular spectra.
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Molecular spectra
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Molecular spectroscopy
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| Form |
Electronic book
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| ISBN |
9781906574413 |
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1906574413 |
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