Time permitting, this lecture also converts well into an activity for students to tackle in small groups.
* Before performing this lecture, it is recommended that students first Approximate the Internal Energy for a 1-D Chain.
A 3-dimensional cube with side length $L$ is filled with a total of $N$ atoms that have spacing $a$ between them.
Find the total energy stored in the lattice when:
a) $T > \frac{\hbar \omega_{max}}{k_{B}}$
b) $T < \frac{\hbar \omega_{max}}{k_{B}}$
a) Just as with the one-dimensional case, the energy stored in the lattice above the “freeze out” zone can be estimated using the equipartition theorem.
$$U_{tot}=\left(\text{Total # modes}\right)\left(k_{B}T\right)=3Nk_{B}T \; \; . $$
b) Before we can find the total energy stored in the cube, we need to properly enumerate the envelope functions that are allowed inside the cube. There are two key things to remember when doing this:
The envelope function that satisfies these conditions is
$$\delta_{n_{x}, n_{y}, n_{z}}=A \sin{\left(k_{x}n_{x}a\right)} \sin{\left(k_{y}n_{y}a\right)} \sin{\left(k_{z}n_{z}a\right)} \; \; , $$
where $n_{x}$, $n_{y}$, and $n_{z}$ all define the location of the atom in real space, while $k_{x}$, $k_{y}$, and $k_{z}$ all define what the wave number is for the envelope function in the x,y, and z orientation.
$$k_{x}=\frac{\pi}{L}, \frac{2\pi}{L}, \frac{3\pi}{L},…$$
$$k_{y}=\frac{\pi}{L}, \frac{2\pi}{L}, \frac{3\pi}{L},…$$
$$k_{z}=\frac{\pi}{L}, \frac{2\pi}{L}, \frac{3\pi}{L},…$$
This will be very important when we try to find all of the modes that are not frozen out for the cube.
Just like in the 1-D case, each point in k-space represents the envelope function $\delta$ that has the wave vectors $k_{x}$, $k_{y}$, and $k_{z}$. The only difference between the three-dimensional case and the one-dimensional case is that we are now looking for all of the normal modes within a volume of radius $k_{freeze}$.
$$\omega(k)=\omega_{max}\sin{\frac{ka}{2}} \; \; , \; \; \; \; \; \; \; \; \; \; \; k=\sqrt{k_{x}^{2}+k_{y}^{2} + k_{z}^{2}} \; \; .$$
Notice that $k$ looks just like a radius, as we anticipated. We can now approximate that $k_{freeze}$ is small to receive
$$\omega_{freeze} \approx \omega_{max}\frac{k_{freeze}{a}}{2} \; \; .$$
Look familiar? We can also determine what $\omega_{freeze}$ is using the phonon energy relation (just like the 1-D case) to find that
$$\frac{k_{B}T}{\hbar}=\omega_{max}\frac{k_{freeze}{a}}{2} \; \; , $$
$$k_{freeze}=\frac{2}{a}\frac{k_{B}T}{\hbar \omega_{max}} \; \; . $$
$$\text{Volume in k-space}=\frac{1}{8}\frac{4\pi}{3}\left(k_{freeze}\right)^{3} \; \; , $$
where the one-eighth is present because we are only looking at positive wave vectors.
$$\text{# modes}=\frac{\text{Total volume with radius} \; k_{freeze}}{\text{Density of wave vectors inside volume}} \; \; .$$
Inserting the information we have will yield
$$\text{# modes}=\frac{(3)\frac{1}{8}\frac{4\pi}{3}\left(k_{freeze}\right)^{3}}{\frac{\pi}{L}^{3}} \; \; ,$$
$$\text{# modes}=\frac{k_{freeze}^{3}L^{3}}{2\pi^{2}} \; \; , \; \; \; \; \; \; \; \text{where} \; \; \; k_{freeze}=\frac{2}{a}\frac{k_{B}T}{\hbar \omega_{max}} \; \; .$$
Notice the multiplication by a factor of 3; this is a consequence of the system being three-dimensional and being driven in three different fashions. For each mode, there are actually two transverse modes and one compression mode.
$$U_{tot}=\left(\frac{2}{a}\frac{k_{B}T}{\hbar \omega_{max}}\right)^{3}\frac{L^{3}}{2\pi^{2}}k_{B}T \; \; .$$
Notice how for the three-dimensional case,
$$U_{tot} \propto T^{4} \; \; , $$
while for the one-dimensional case,
$$U_{tot} \propto T \; \; . $$
$$C_{v}=\left(\frac{dU_{tot}}{dT}\right)_{v} \; \; . $$