Solution to Set 5: Difference between revisions

I have no idea what I'm doing - KimberlyWynne 03:11, 2 March 2009 (EST)

Diatomic harmonic chain

Problem 1

Given:

• a chain of atoms
• with alternating masses ${\displaystyle m_{1}\;}$ and ${\displaystyle m_{2}\;}$
• connected with elastic springs with constant ${\displaystyle K\;}$
• moving only in the x-direction

Derive the dispersion relation ${\displaystyle \omega ^{\alpha }(k)\;}$ for this chain

• Index ${\displaystyle \alpha =1\;}$ for acoustic branch
• Index${\displaystyle \alpha =2\;}$ for optical branch

Potential Energy ${\displaystyle U=1,2,3,...n\;}$

${\displaystyle U\cong {\frac {1}{2}}k\sum _{n}(U_{n}-U_{n-1})\;}$

${\displaystyle \Rightarrow m{\ddot {U}}_{n}=-k[2U_{n}-U_{n-1}-U_{n+1}]\;}$

Eigenvector Value for modes

${\displaystyle u_{m}(t)=e^{i\omega t}u_{m}\;}$

What does the subscript m stand for? Modes? KimberlyWynne 03:36, 2 March 2009 (EST)

${\displaystyle \Rightarrow -m\omega ^{2}{\vec {u}}=-k\mathbf {M} {\vec {u}}\;}$

Band Matrix ${\displaystyle \mathbf {M} ={\begin{vmatrix}2&1&0&0\\1&2&1&0\\0&1&2&1\\0&0&1&2\end{vmatrix}}}$

${\displaystyle u_{m}(t)=e^{ik(na)-\omega t}\;}$ where ${\displaystyle u_{m}\rightarrow u_{n}e^{ik(na)}\;}$

${\displaystyle \Rightarrow -m\omega ^{2}{\vec {u}}=-k[2-e^{ik\alpha }-e^{-ik\alpha }]\;}$

Problem 2

Determine the speed of sound for this chain. What is the lowest frequency of long-wavelength sound corresponding to the optical branch?

From my lecture notes: ${\displaystyle \omega _{\alpha }(k)\approx C_{\alpha }k\;}$

where ${\displaystyle C_{\alpha }}$ = speed of sound

Problem 3

Sketch the motion of the atoms corresponding to the edge of the Brillouin zone, both for the optical and the acoustic branch.

Problem 4

Determine the Debye temperature for this system, and determine the form of the specific heat ${\displaystyle c_{V}(T)}$ in the limits of high and low temperatures.

Problem 5

Consider low temperatures (${\displaystyle T\ll T_{D}\;}$) and determine the wavelength of the most abundant phonons ${\displaystyle \lambda _{max}}$ (Hint: note the analogy with Wien's Law!)