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==Problem 1==
==Problem 1==


Consider a ''tight-binding'' Hamiltonian of 1D nanowire:
Consider a tight-binding model of a 1D nanowire:


<math> \hat{H} = \sum_m \cos(2 \pi m \alpha) |m \rangle \langle m| +  t \sum_m  \frac{1}{2} \left ( |m \rangle \langle m+1 | + |m \rangle \langle m-1| \right)</math>,
<math> \hat{H} = \sum_m \cos\left(2 \pi m \frac{5}{3}\right) |m \rangle \langle m| +  t \sum_m  \frac{1}{2} \left ( |m \rangle \langle m+1 | + |m \rangle \langle m-1| \right)</math>,


where $\alpha=5/3$. The integer $m$ should be thought of as indexing sites along the chain of atoms. The ket $| m \rangle$ locates an electron on atom $m$ (e.g., $\langle x | m \rangle =  \psi(x-m)$ is the wave function, or "orbital", which decays fast away from the position of an atom m).
The integer <math> m </math> is indexing sites at which the atoms are located. The distance between two sites defined the lattice spacing <math> a </math>. The ket <math>| m \rangle</math> is quantum state of an electron on atom <math> m </math>, so that <math>\langle x | m \rangle =  \psi(x-m)</math> is the corresponding wave function in coordinate representation (or single "orbital" per site) which decays fast away from the position of an atom <math> m</math>.


\smallskip
(a) What is the periodicity of the Hamiltonian? That is, after how many atoms the chain starts to repeat itself. This atoms define the unit cell of the wire whose periodic repetition in both direction


(a) What is the periodicity of the Hamiltonian?
(b) Use Bloch theorem to reduce the eigenvalue problem of an infinite matrix <math> \mathbf{H} </math>, obtained by representing the  Hamiltonian in the basis of orbitals <math> |m \rangle </math>, to diagonalization of  a small matrix [whose size <math> n </math> is equal to the periodicity of the Hamiltonian found in (a)].


\smallskip
(c) The <math> n \times n </math> matrix in (b) will depended on the Bloch wave vector <math> k </math>. Compute and plot <math> n </math> bands as a function of Bloch wave vector <math> k </math> throughout the first Brillouin zone (this task will have to be carried our numerically).
 
(b) Use Bloch theorem to reduce the eigenvalue problem of an infinite matrix $\hat{H}$ (obtained by representing the  Hamiltonian in the basis of orbitals $|m\rangle$) to the solution of a small {\em finite} matrix equation [note that the size of this matrix will be equal to the periodicity of the Hamiltonian found in (a)].
 
\smallskip
 
(c) Compute and plot the bands as a function of Bloch wave vector $k$ throughout the first Brillouin zone (this task will have to be carried our numerically).}


==Problem 2==
==Problem 2==

Revision as of 22:39, 18 September 2009

Problem 1

Consider a tight-binding model of a 1D nanowire:

,

The integer is indexing sites at which the atoms are located. The distance between two sites defined the lattice spacing . The ket is quantum state of an electron on atom , so that is the corresponding wave function in coordinate representation (or single "orbital" per site) which decays fast away from the position of an atom .

(a) What is the periodicity of the Hamiltonian? That is, after how many atoms the chain starts to repeat itself. This atoms define the unit cell of the wire whose periodic repetition in both direction

(b) Use Bloch theorem to reduce the eigenvalue problem of an infinite matrix , obtained by representing the Hamiltonian in the basis of orbitals , to diagonalization of a small matrix [whose size is equal to the periodicity of the Hamiltonian found in (a)].

(c) The matrix in (b) will depended on the Bloch wave vector . Compute and plot bands as a function of Bloch wave vector throughout the first Brillouin zone (this task will have to be carried our numerically).

Problem 2

Problem 3

Problem 4

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