- #1
ian2012
- 77
- 0
I hope someone can help me out here,
I am confused with a line of text I read - it is an example of a 2D Hilbert space with orthonormal basis e1, e2. The Hamiltonian of the system is the Pauli matrix in the y-direction. Given by the matrix:
\sigma_{y} = (\frac{0, -i}{i, 0})
The eigenvectors of the Hamiltonian are given by:
| \pm >_{y}= \frac{1}{\sqrt{2}}(| e_{1} > \pm i|e_{2}>)
So, applying the time evolution operator to the eigenvectors gives:
U| \pm >_{y}=exp(\frac{-i(t-t_{0}) \sigma_{y}}{\hbar})| \pm >_{y}
U| \pm >_{y}=exp(\frac{\mp i(t-t_{0})}{\hbar})| \pm >_{y}
I don't understand how the last line came about?
I am confused with a line of text I read - it is an example of a 2D Hilbert space with orthonormal basis e1, e2. The Hamiltonian of the system is the Pauli matrix in the y-direction. Given by the matrix:
\sigma_{y} = (\frac{0, -i}{i, 0})
The eigenvectors of the Hamiltonian are given by:
| \pm >_{y}= \frac{1}{\sqrt{2}}(| e_{1} > \pm i|e_{2}>)
So, applying the time evolution operator to the eigenvectors gives:
U| \pm >_{y}=exp(\frac{-i(t-t_{0}) \sigma_{y}}{\hbar})| \pm >_{y}
U| \pm >_{y}=exp(\frac{\mp i(t-t_{0})}{\hbar})| \pm >_{y}
I don't understand how the last line came about?
