Phonons and reciprocal space

From ChemWiki
Revision as of 12:01, 24 August 2018 by Vc2115 (Talk | contribs)

Jump to: navigation, search

Vibrations

Recall that vibrations are dene as the oscillation (or movement) of atoms in a molecule (or crystal) in periodic motion. In the crystalline case, these periodic vibrations are known as phonons. The simplest approximation to describe this periodic motion (i.e. phonons) is that of the harmonic oscillator that is shown in Fig. 1 and described by Eq. 1.

Simple harmonic motion animation.gif x(t) = Acos(\omega t + \phi) (Eq. 1)
Fig. 1: Animation of a simple harmonic oscillator. A and \phi is the amplitud and the phase respectively and \omega is the angular frequency

If we consider the bonds between atoms as elastic strings, we can consider the Hooke's Law (Eq. 2) as a good approximation.

F= -k \Delta x \qquad E = \frac{kx^2}{2} \qquad k = \omega^2 m

Here k denotes the spring constant and m is the mass.

Vibrations in Solid State

In a simulation, we are �rst required to describe the system we are going to study. The "system" refers to the solid-state structure we want to investigate. Solid-state, by contrast to molecular science, makes use of the periodicity of a structure. Since the size of the crystal (or periodic tessellation of atoms) is signi�ficantly larger than the size of a single molecule in most cases, we assume that the number of atoms and structure of the crystal is in�nite. Of course, not all solids have a perfect periodic arrangement and this makes things very complicated to simulate, however we will assume that our structure has a periodic arrangement.

As starting point, the simplest model where atoms are arranged periodically in space is the 1D chain of atoms with the same mass equally spaced by a (Notice that a is the equilibrium distance between atoms). Remember that in a vibration, the motion of the atoms can be described as a harmonic oscillator. Fig. 2 represent a 1D chain of atoms in a vibrational mode where the atoms are moving in anti-phase.

From Fig. 2 we note that when the atoms are far away from the equilibrium distance (Fig. 2 left and right), the energy will increase and when the distance between atoms is the same as the equilibrium distance (Fig. 2 centre), the energy is a minima. It is therefore possible to describe the change of the energy as a function of the position of the atoms in a vibrational mode with a function (Fig. 2 lower waves). To sum up, we have demonstrate that we only need a simple periodic function to describe the motion of the atoms in a crystal in a vibrational mode.

The next step is �guring out how many di�erent vibrational modes are in a crystal. A simple rule to fi�nd the number of di�fferent vibrations is that the number of vibrational modes in a molecule is equal to 3N-6 (or 3N-5 if the molecule is linear) where N is the number of atoms. However, in a crystal we have an in�nite number of atoms and therefore, we expected an in�nite number of vibrational modes. In Fig. 2 we have de�ne a vibrational wave that corresponds to the moment where all the atoms are moving in antiphase. The opposite case, where all the atoms are moving in phase is shown in Fig. 3. When all the atoms are moving in phase, there is no change in the distance between atoms and the energy is constant. Since there is no change in energy (the frequency is equal to zero), the function that describes this vibration is a straight line.

Retrieved from "https://wiki.ch.ic.ac.uk/wiki/index.php?title=Phonons_and_reciprocal_space&oldid=734302"