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• Week 1:Classification of spectroscopy. Rotational spectra of rigid linear molecules and determination of bond lengths. The stark-effect.
• Week 2:Harmonic and anharmonic oscillator models for the energy of a diatomic molecule.
• Week 3:Types of vibrational modes. Interpretation of IR spectra of simple molecules.
• Week 4:Fermi resonance, applications and sampling techniques.
• Week 5:Types of electronic transition.
• Week 6:H–atom spectrum, energies of atomic orbital, electronic angular momentum and the fine structure.
• Week 7:H–atom spectrum, energies of atomic orbital, electronic angular momentum and the fine structure.
• Week 8:H–atom spectrum, energies of atomic orbital, electronic angular momentum and the fine structure.
• Week 9:Idea of Raman scattering, Rayleigh scattering and molecular polarizability. Rotational Raman spectra of linear molecules.
• Week 10: Idea of Raman scattering, Rayleigh scattering and molecular polarizability. Rotational Raman spectra of linear molecules.
• Week 11: Idea of Raman scattering, Rayleigh scattering and molecular polarizability. Rotational Raman spectra of linear molecules.
• Week 11: Symmetric top molecules and spherical top molecules, vibrational Raman spectra.
• Week 12: Symmetric top molecules and spherical top molecules, vibrational Raman spectra.
• Week 13: Nuclear magnetic resonance spectroscopy
• Week 14: Interpretation of IR spectra of simple molecules. Fermi resonance, applications and sampling techniques
• Week 15: Interpretation of IR spectra of simple molecules. Fermi resonance, applications and sampling techniques
• Week 16: Harmonic and anharmonic oscillator models for the energy of a diatomic molecule.
• Week 17: Harmonic and anharmonic oscillator models for the energy of a diatomic molecule.