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Beyond Beer's Law: Revisiting the Lorentz‐Lorenz Equation

Thomas G. Mayerhöfer, Jürgen Popp

2020ChemPhysChem58 citationsDOIOpen Access PDF

Abstract

In this contribution we show how the Lorentz-Lorenz and the Clausius-Mosotti equations are related to Beer's law. Accordingly, the linear concentration dependence of absorbance is a consequence of neglecting the difference between the local and the applied electric field. Additionally, it is necessary to assume that the absorption index and the related refractive index change is small. By connecting the Lorentz-Lorenz equations with dispersion theory, it becomes obvious that the oscillators are coupled via the local field. We investigate this coupling with numerical examples and show that, as a consequence, the integrated absorbance of a single band is in general no longer linearly depending on the concentration. In practice, the deviations from Beer's law usually do not set in before the density reaches about one tenth of that of condensed matter. For solutions, the Lorentz-Lorenz equations predict a strong coupling also between the oscillators of solute and solvent. In particular, in the infrared spectral region, the absorption coefficients are prognosticated to be much higher due to this coupling compared to those in the gas phase.

Topics & Concepts

Lorentz transformationPhysicsMathematical physicsThermodynamicsTheoretical physicsClassical mechanicsScientific Research and DiscoveriesAdvanced Thermodynamics and Statistical MechanicsSpectroscopy and Laser Applications
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