- Find the (normalized) eigenvectors and eigenvalues of theSx(matrix) operator fors= 1 in
the usual (Sz) basis.
6.*A spin^12 particle is in a magnetic field in thexdirection giving a HamiltonianH=μBBσx.Find the time development (matrix) operatore−iHt/ ̄hin the usual basis. Ifχ(t= 0) =(
1
0
)
,
findχ(t).- A spin^12 system is in the following state in the usualSzbasis:χ=√^15
(√
3
1 +i)
. What is the
probability that a measurement of thexcomponent of spin yields +^12?- A spin^12 system is in the stateχ=√^15
(
i
2)
(in the usualSzeigenstate basis). What is theprobability that a measurement ofSxyields− 2 h ̄? What is the probability that a measurement
ofSyyields− 2 ̄h?- A spin^12 object is in an eigenstate ofSy with eigenvalue ̄h 2 at t=0. The particle is in a
magnetic fieldB= (0, 0 ,B) which makes the Hamiltonian for the systemH=μBBσz. Find
the probability to measureSy= ̄h 2 as a function of time. - Two degenerate eigenfunctions of the Hamiltonian are properlynormalized and have the fol-
lowing properties.
Hψ 1 =E 0 ψ 1 Hψ 2 =E 0 ψ 2
Pψ 1 =−ψ 2 Pψ 2 =−ψ 1What are the properly normalized states that are eigenfunctions of H and P? What are their
energies?- What are the eigenvectors and eigenvalues for the spin^12 operatorSx+Sz?
- A spin^12 object is in an eigenstate ofSy with eigenvalue ̄h 2 at t=0. The particle is in a
magnetic fieldB= (0, 0 ,B) which makes the Hamiltonian for the systemH=μBBσz. Find
the probability to measureSy= ̄h 2 as a function of time. - A spin 1 system is in the following state, (in the usualLzeigenstate basis):
χ=1
√
5
√i
2
1 +i
.
What is the probability that a measurement ofLxyields 0? What is the probability that a
measurement ofLyyields− ̄h?- A spin^12 object is in an eigenstate ofSz with eigenvalue ̄h 2 at t=0. The particle is in a
magnetic fieldB= (0,B,0) which makes the Hamiltonian for the systemH=μBBσy. Find
the probability to measureSz= ̄h 2 as a function of time. - A spin 1 particle is placed in an external field in theudirection such that the Hamiltonian is
given by
H=α(√
3
2
Sx+1
2
Sy)
Find the energy eigenstates and eigenvalues.