- #1
Abigale
- 56
- 0
Hey,
I consider a diagonalized Hamiltonian:
[itex]H=\sum\limits_{k} \underbrace{ (\epsilon_{k} u_{k}^2 -\epsilon_{k} v_{k}^2 -2\Delta u_{k} v_{k} )}_{E_{k}}(d_{k \uparrow}^{\dagger}d_{k \uparrow} + d_{k \downarrow}^{\dagger}d_{k \downarrow}) +const [/itex]
with fermionic creation and annihilation operators.
From solution I know that: [itex]E_{k} =\sqrt{\Delta^2 +\epsilon_{k}^2}[/itex] but how can I get this result?
Things I even know is that: [itex]u_k^2 + v_k^2 =1 [/itex] and:
[itex]\sum\limits_k
\underbrace{(
-2\epsilon_k u_k v_k +\Delta v_k^2 -\Delta u_k ^2
)}_{\stackrel{!}{=}0}
(d_{k \uparrow}^{\dagger}d_{k \downarrow}^{\dagger} + d_{k \downarrow}d_{k \uparrow})[/itex].
Thank you guys!
I consider a diagonalized Hamiltonian:
[itex]H=\sum\limits_{k} \underbrace{ (\epsilon_{k} u_{k}^2 -\epsilon_{k} v_{k}^2 -2\Delta u_{k} v_{k} )}_{E_{k}}(d_{k \uparrow}^{\dagger}d_{k \uparrow} + d_{k \downarrow}^{\dagger}d_{k \downarrow}) +const [/itex]
with fermionic creation and annihilation operators.
From solution I know that: [itex]E_{k} =\sqrt{\Delta^2 +\epsilon_{k}^2}[/itex] but how can I get this result?
Things I even know is that: [itex]u_k^2 + v_k^2 =1 [/itex] and:
[itex]\sum\limits_k
\underbrace{(
-2\epsilon_k u_k v_k +\Delta v_k^2 -\Delta u_k ^2
)}_{\stackrel{!}{=}0}
(d_{k \uparrow}^{\dagger}d_{k \downarrow}^{\dagger} + d_{k \downarrow}d_{k \uparrow})[/itex].
Thank you guys!