X-Git-Url: https://hackdaworld.org/gitweb/?p=lectures%2Flatex.git;a=blobdiff_plain;f=solid_state_physics%2Ftutorial%2F1_02s.tex;h=6f920e8bcfc9f7f56e909f52db0231d4658f45e4;hp=2827bb7d27dc620326c994cff48099e3ae72c6e4;hb=79c30f13ba31a3d5988133db6e6992235b64ca8a;hpb=4eae86611e1b7f0613e8d7109ae0473b85672f90 diff --git a/solid_state_physics/tutorial/1_02s.tex b/solid_state_physics/tutorial/1_02s.tex index 2827bb7..6f920e8 100644 --- a/solid_state_physics/tutorial/1_02s.tex +++ b/solid_state_physics/tutorial/1_02s.tex @@ -34,7 +34,7 @@ Prof. B. Stritzker\\ WS 2007/08\\ \vspace{8pt} - {\Large\bf Tutorial 2} + {\Large\bf Tutorial 2 - proposed solutions} \end{center} \section{Phonons 1} @@ -117,11 +117,15 @@ $M_1\ddot{u}_s=C(v_s+v_{s-1}-2u_s)$\\ $M_2\ddot{v}_s=C(u_{s+1}+u_s-2v_s)$ \item Ansatz:\\ - $u_s=u\exp{i(ska-\omega t)}$\\ - $v_s=v\exp{i(ska-\omega t)}$ + $u_s=u\exp(i(ska-\omega t))$\\ + $v_s=v\exp(i(ska-\omega t))$ \item Solution of the equation system:\\ - $-\omega^2M_1u=Cv[1+\exp(-ika)]-2Cu$\\ - $-\omega^2M_2v=Cu[\exp(ika)+1]-2Cv$\\ + $-\omega^2M_1u\exp(i(ska-\omega t))= + C\exp(-i\omega t)[v\exp(iska)+v\exp(i(s-1)ka)-2u\exp(iska)]$\\ + $\Rightarrow -\omega^2M_1u=Cv(1+\exp(-ika))-2Cu$\\ + $-\omega^2M_2v\exp(i(ska-\omega t))= + C\exp(-i\omega t)[u\exp(i(s+1)ka)+u\exp(iska)-2v\exp(iska)]$\\ + $\Rightarrow -\omega^2M_2v=Cu[\exp(ika)+1]-2Cv$\\ Non trivial solution only if determinant of coefficients $u$ and $v$ is zero.\\ $\Rightarrow @@ -131,6 +135,11 @@ -C[1+\exp(ika)] & 2C-M_2\omega^2 \end{array} \right|=0$\\ + $\Rightarrow + 4C^2+M_1M_2\omega^4-2C\omega^2(M_2+M_1)- + \underbrace{C^2(1+\exp(ika))(1+\exp(-ika))}_{ + C^2(\underbrace{1+1+\exp(ika)+\exp(-ika)}_{ + 2+2\cos(ka)=2(1+\cos(ka))})}$\\ $\Rightarrow M_1M_2\omega^4-2C(M_1+M_2)\omega^2+2C^2(1-\cos(ka))=0$ \end{itemize}