5.2: Background on Rotovibrational Spectroscopy

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A note from your instructors

We are working to replace the commercial textbooks used in this course. While we're still working on it, we are providing the following sections (which are still under construction). The section on transition intensities is the only section that was part of the original manual for this course, and is not covered in the Shoemaker textbook.

5.2.1: The Electromagnetic Spectrum and Molecular Transitions
Electromagnetic radiation—light—is a form of energy whose behavior is described by the properties of both waves and particles. Some properties of electromagnetic radiation, such as its refraction when it passes from one medium to another are explained best by describing light as a wave. Other properties, such as absorption and emission, are better described by treating light as a particle.
5.2.2: Rotational Transitions Accompany Vibrational Transitions
Each of the modes of vibration of diatomic molecules in the gas phase also contains closely-spaced (1-10 cm-1 difference) energy states attributable to rotational transitions that accompany the vibrational transitions. A molecule’s rotation can be affected by its vibrational transition because there is a change in bond length, so these rotational transitions are expected to occur. Since vibrational energy states are on the order of 1000 cm-1, the rotational energy states can be superimposed upon
5.2.3: Transition Intensities
5.2.4: The Pure Rotational Spectrum has Unequal Spacings
Vibrational energy which is a consequence of the oscillations/ vibrations of the nuclei along inter nuclear axis, is possible only when the distance between the nuclei is not fixed/ rigid; that means the separation between the two nuclei is flexible/ elastic (non-rigid rotor). Consequently, centrifugal force, when the molecule is rotating, tends to fly the reduced mass μ away from the axis of rotation.
5.2.5: Anharmonicity and Vibrational Overtones
Combination bands, overtones, and Fermi resonances are used to help explain and assign peaks in vibrational spectra that do not correspond with known fundamental vibrations. Combination bands and overtones generally have lower intensities than the fundamentals. Hot bands will also be briefly addressed.

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