6: Classical Description of Spectroscopy

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6.1: Introduction
The classical description of spectroscopy in the time-domain provides the physical intuition on concepts of resonance, polarizability, and Fourier transform relationships that one uses in quantum mechanical models.
6.2: Absorption by a Driven Oscillator
The classical driven harmonic oscillator model for spectroscopy describes the interaction of light with bound charged particles using Newton’s equation of motion F=ma.
6.3: Complex formulation of the driven dipole oscillator
We repeat the driven oscillator in terms of an induced dipole driven by an electric field using a complex formulation.
6.4: Response of an Impulsively Driven Oscillator
We describe the driven oscillator in the time domain using a response function.
6.5: Polarizability
Polarizability refers to the ability of electromagnetic radiation to shift electron density within molecules and thereby induce dipole moments. We discuss this for classical atoms and the driven oscillator model.

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