Temporary HW: Difference between revisions

Revision as of 17:47, 16 February 2011

Problem 1

A researcher in spintronics is investigated two devices in order to generate spin-polarized currents. One of those devices has spins comprising the current described by the density matrix:

${\hat {\rho }}_{1}={\frac {|\uparrow \rangle \langle \uparrow |+|\downarrow \rangle \langle \downarrow |}{2}}$ ,

while the spins comprising the current in the other device are described by the density matrix

${\hat {\rho }}_{2}=|u\rangle \langle u|$ , where $\ |u\rangle ={\frac {e^{i\alpha }|\uparrow \rangle +e^{i\beta }|\downarrow \rangle }{\sqrt {2}}}$ .

Here $|\uparrow \rangle$ and $|\downarrow \rangle$ are the eigenstates of the Pauli spin matrix ${\hat {\sigma }}_{z}$ :

${\hat {\sigma }}_{z}|\uparrow \rangle =+1|\uparrow \rangle ,\ {\hat {\sigma }}_{z}|\downarrow \rangle =-1|\downarrow \rangle$ .

What is the spin polarization of these two currents? Comment on the physical meaning of the difference between the spin state transported by two currents.

HINT: Compute the x, y, and z components of the spin polarization vector using both of these density matrices following the quantum-mechanical definition of an average value $P_{x,y,z}=\langle \sigma _{x,y,z}\rangle =\mathrm {Tr} \,[{\hat {\rho }}{\hat {\sigma }}_{x,y,z}]$ .

Problem 2

The Hamiltonian of a single spin in external magnetic field $\mathbf {B}$ is given by (assuming that gyromagnetic ration is unity):

${\hat {H}}=-{\frac {\hbar }{2}}\mathbf {B} \cdot {\vec {\sigma }}$

where ${\vec {\sigma }}=({\hat {\sigma }}_{x},{\hat {\sigma }}_{y},{\hat {\sigma }}_{z})$ is the vector of the Pauli matrices. Show that the equation of motion

$i\hbar {\frac {\partial \mathbf {\rho } }{\partial t}}=[{\hat {H}},\mathbf {\rho } ]$

for the density matrix of spin- ${\frac {1}{2}}$ discussed in the class

$\mathbf {\rho } ={\frac {1}{2}}\left(1+\mathbf {P} \cdot \mathbf {\sigma } \right)$

can be recast into the equation of motion for the Bloch polarization vector

${\frac {d\mathbf {P} }{dt}}$

since $\mathbf {\rho }$ and $\mathbf {P}$ are in one-to-one correspondence. Remember that

${\hat {\sigma }}_{i}{\hat {\sigma }}_{j}-{\hat {\sigma }}_{j}{\hat {\sigma }}_{i}=2i\epsilon _{ijk}{\hat {\sigma }}_{k}$ .

@@ Line 28: / Line 28: @@
 The Hamiltonian of a single spin in external magnetic field <math> \mathbf{B} </math> is given by (assuming that gyromagnetic ration is unity):
-<math> \hat{H} = -\frac{\hbar}{2} \mathbf{B} \cdot \mathbf{\sigma} </math>
+<math> \hat{H} = -\frac{\hbar}{2} \mathbf{B} \cdot \vec{\sigma} </math>
-where <math> \mathbf{\sigma}=(\sigma_x,\sigma_y,\sigma_z) </math> is the vector of the Pauli matrices. Show that the equation of motion
+where <math> \vec{\sigma}=(\hat{\sigma}_x,\hat{\sigma}_y,\hat{\sigma}_z) </math> is the vector of the Pauli matrices. Show that the equation of motion
 <math> i \hbar \frac{\partial \mathbf{\rho}}{\partial t} = [\hat{H},\mathbf{\rho}] </math>
@@ Line 38: / Line 38: @@
 <math> \mathbf{\rho} = \frac{1}{2} \left( 1 + \mathbf{P} \cdot \mathbf{\sigma} \right) </math>
-can be written as:
+can be recast into the equation of motion for the Bloch polarization vector
-<math> \frac{dP}{dt} </math>
+<math> \frac{d \mathbf{P}}{dt} </math>
+since <math> \mathbf{\rho} </math> and <math> \mathbf{P} </math> are in one-to-one correspondence. Remember that
+<math> \hat{\sigma}_i \hat{\sigma}_j - \hat{\sigma}_j \hat{\sigma}_i = 2 i \epsilon_{ijk} \hat{\sigma}_k </math>.
 == Problem 3 ==

Temporary HW: Difference between revisions

Revision as of 17:47, 16 February 2011

Problem 1

Problem 2

Problem 3

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