Debye vs. Einstein. Predicted heat capacity as a function of temperature.
So how closely do the Debye and Einstein models correspond to experiment?
Surprisingly close, but Debye is correct at low temperatures whereas Einstein is not.
How different are the models? To answer that question one would naturally plot the two on the same set of axes... except one can't. Both the Einstein model and the Debye model provide a functional form for the heat capacity. They are models, and no model is without a scale. A scale relates the model to its real-world counterpart.
One can see that the scale of the Einstein model, which is given by
is ε / k. And the scale of the Debye model is TD, the Debye temperature. Both are usually found by fitting the models to the experimental data. (The Debye temperature can theoretically be calculated from the speed of sound and crystal dimensions.)
Because the two methods approach the problem from different directions and different geometries, Einstein and Debye scales are not the same, that is to say
which means that plotting them on the same set of axes makes no sense. They are two models of the same thing, but of different scales. If one defines Einstein temperature as
then one can say
and, to relate the two, we must seek the ratio
The Einstein solid is composed of single-frequency quantum harmonic oscillators,
.
That frequency, if it indeed existed, would be related to the speed of sound in the solid. If one imagines the propagation of sound as a sequence of atoms hitting one another, then it becomes obvious that the frequency of oscillation must correspond to the minimum wavelength sustainable by the atomic lattice, λmin.
That frequency, if it indeed existed, would be related to the speed of sound in the solid. If one imagines the propagation of sound as a sequence of atoms hitting one another, then it becomes obvious that the frequency of oscillation must correspond to the minimum wavelength sustainable by the atomic lattice, λmin.
which makes the Einstein temperature
and the sought ratio is therefore
Now both models can be plotted on the same graph. Note that this ratio is the cube root of the ratio of the volume of one octant of a 3-dimensional sphere to the volume of the cube that contains it, which is just the correction factor used by Debye when approximating the energy integral above
Kevin M Contreras H
Electrónica del Estado Sólido
http://en.wikipedia.org/wiki/Debye_Theory
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