Homework Set 2: Difference between revisions

Revision as of 17:52, 28 February 2012

Problem 1

The Hamiltonian for an electron spin degree of freedom in the external magnetic field $\mathbf {B}$ is given by:

${\hat {H}}=-\mu _{B}{\vec {\sigma }}\cdot \mathbf {B}$

where $\mu _{B}$ is the Bohr magneton and ${\vec {\sigma }}=({\hat {\sigma }}_{x},{\hat {\sigma }}_{y},{\hat {\sigma }}_{z})$ is the vector of the Pauli matrices:

${\hat {\sigma }}_{x}={\begin{pmatrix}0&1\\1&0\end{pmatrix}},$

${\hat {\sigma }}_{y}={\begin{pmatrix}0&-i\\i&0\end{pmatrix}},$

${\hat {\sigma }}_{z}={\begin{pmatrix}1&0\\0&-1\end{pmatrix}}.$

(a) In the quantum canonical ensemble, evaluate the density matrix if $\mathbf {B}$ is along the z axis.

(b) Repeat the calculation from (a) assuming that $\mathbf {B}$ points along the x axis.

(c) Calculate the average energy in each of the above cases.

Problem 2

Consider a single one-dimensional quantum harmonic oscillator described by the Hamiltonian:

${\hat {H}}={\frac {{\hat {p}}^{2}}{2m}}+{\frac {m\omega ^{2}q^{2}}{2}}$ ,

where ${\hat {p}}=-i{\hbar }{\frac {d}{dq}}$ .

(a) Find the partition function $Z$ in quantum canonical ensemble at temperature $T$ .

(b) Using result from (a), calculate the averge energy $E=\langle {\hat {H}}\rangle$ .

(c) Write down the formal expression for the canonical density operator ${\hat {\rho }}$ in terms of the eigenstates $|n\rangle$ of the Hamiltonian and the corresponding energy levels $\varepsilon _{n}=\hbar \omega (n+1/2)$ .

(d) Using result in (c), write down the density matrix in a coordinate representation $\langle q'|{\hat {\rho }}|q\rangle$ .

(e) In the coordinate representation, calculate explicitly $\langle q'|{\hat {\rho }}|q\rangle$ in the high temperature limit $T\rightarrow \infty$ .

HINT: One approach is to utilize the following result

$e^{\beta {\hat {A}}}e^{\beta {\hat {B}}}=e^{\beta ({\hat {A}}+{\hat {B}})+\beta ^{2}[{\hat {A}},{\hat {B}}]/2+O(\beta ^{3})}$

which you can apply to the Boltzmann operator:

$e^{-\beta {\hat {H}}}=e^{-\beta {\frac {{\hat {p}}^{2}}{2m}}-\beta {\frac {m\omega ^{2}q^{2}}{2}}}$

while neglecting terms of order $\beta ^{2}$ and higher since $\beta$ is very small in the high temperature limit.

(f) At low temperatures, ${\hat {\rho }}$ is dominated by low-energy states. Use the ground state wave function $\langle q|0\rangle$ only, evaluate the limiting behavior of $\langle q'|{\hat {\rho }}|q\rangle$ as $T\rightarrow 0$ .

@@ Line 28: / Line 28: @@
 </math>
-(a) In the quantum canonical ensemble, evaluate the density matrix if <math> \mathbf{B} </math> is along the ''z'' axis.
+'''(a)''' In the quantum canonical ensemble, evaluate the density matrix if <math> \mathbf{B} </math> is along the ''z'' axis.
-(b) Repeat the calculation from (a) assuming that <math> \mathbf{B} </math> points along the ''x'' axis.
+'''(b)''' Repeat the calculation from (a) assuming that <math> \mathbf{B} </math> points along the ''x'' axis.
-(c) Calculate the average energy in each of the above cases.
+'''(c)''' Calculate the average energy in each of the above cases.
 == Problem 2 ==
@@ Line 42: / Line 42: @@
 where <math> \hat{p} = -i{\hbar} \frac{d}{dq} </math>.
-(a) Find the partition function <math> Z </math> in quantum canonical ensemble at temperature <math> T </math>.
+'''(a)''' Find the partition function <math> Z </math> in quantum canonical ensemble at temperature <math> T </math>.
-(b) Using result from (a), calculate the averge energy <math> E =  \langle \hat{H} \rangle </math>.
+'''(b)''' Using result from (a), calculate the averge energy <math> E =  \langle \hat{H} \rangle </math>.
-(c) Write down the formal expression for the canonical density operator <math> \hat{\rho} </math> in terms of the eigenstates <math> |n\rangle </math> of the Hamiltonian and the corresponding energy levels <math> \varepsilon_n = \hbar \omega (n + 1/2) </math>.
+'''(c)''' Write down the formal expression for the canonical density operator <math> \hat{\rho} </math> in terms of the eigenstates <math> |n\rangle </math> of the Hamiltonian and the corresponding energy levels <math> \varepsilon_n = \hbar \omega (n + 1/2) </math>.
-(d) Using result in (c), write down the density matrix in a coordinate representation <math> \langle q' |\hat{\rho}|q\rangle </math>.
+'''(d)''' Using result in (c), write down the density matrix in a coordinate representation <math> \langle q' |\hat{\rho}|q\rangle </math>.
-(e) In the coordinate representation, calculate explicitly <math> \langle q' |\hat{\rho}|q\rangle </math> in the high temperature limit <math> T \rightarrow \infty </math>.
+'''(e)''' In the coordinate representation, calculate explicitly <math> \langle q' |\hat{\rho}|q\rangle </math> in the high temperature limit <math> T \rightarrow \infty </math>.
-HINT: One approach is to utilize the following result
+'''HINT:''' One approach is to utilize the following result
 <math> e^{\beta \hat{A}} e^{\beta \hat{B}} = e^{\beta(\hat{A} + \hat{B}) + \beta^2 [\hat{A},\hat{B}]/2 + O(\beta^3)} </math>
@@ Line 62: / Line 62: @@
 while neglecting terms of order <math> \beta^2 </math>  and higher since <math> \beta </math> is very small in the high temperature limit.
-(f) At low temperatures, <math> \hat{\rho} </math> is dominated by low-energy states. Use the ground state wave function <math> \langle q|0 \rangle </math> only, evaluate the limiting behavior of <math> \langle q' |\hat{\rho}|q\rangle </math> as <math> T \rightarrow 0 </math>.
+'''(f)''' At low temperatures, <math> \hat{\rho} </math> is dominated by low-energy states. Use the ground state wave function <math> \langle q|0 \rangle </math> only, evaluate the limiting behavior of <math> \langle q' |\hat{\rho}|q\rangle </math> as <math> T \rightarrow 0 </math>.

Homework Set 2: Difference between revisions

Revision as of 17:52, 28 February 2012

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