Problem 1:
Consider the matrices A and B.
(a) Argue why both matrices are diagonalizable. No calculation allowed.
(b) Find the eigenvalues and eigenvectors of A.
(c) Find [A,B].
(d) The similarity transformation B' = Q-1BQ
diagonalizes matrix B. Find Q and Q-1.
Solution:
- Concepts:
Matrix algebra
- Reasoning:
This is a linear algebra problem.
- Details of the calculation:
(a) Both matrices are Hermitian and thus diagonalizable.
(b)
The third equation is redundant.
Multiply first equation by a factor of 4 and subtract:
--> y = 0. Then x = -z.
eigenvector 1:
Solving this system of equations yields x = y = z.
eigenvector 2:
Solving this system of equations yields x = z, y = -2x.
eigenvector 3:
Note that all three vectors are orthogonal, as they should since are
non-degenerate.
(c)
Therefore [A,B] = 0.
(d) Since A and B commute, they have a common set of eigenvectors. Hence the
eigenvectors of A form the columns of the matrix Q that diagonalizes matrix B. In other words, B' = Q-1BQ is a diagonal matrix with the eigenvalues
of B appearing on the diagonal.
If we use the normalized eigenvectors of A, then Q will be unitary,
which makes it easy to Q-1 = Q†.
Problem 2:
You prepare an ensemble of identical experiments at t = 0. You measure the
values of a physical observable A at time t = t1 > 0 in all of the
experiments of the ensemble. At time t2 > t1 you measure
observable A again in all of the experiments, i.e. you follow the measurement
at t = t1 in each experiment with a subsequent measurement of A in
each experiment at t = t2.
True or False: (Explain your choice in one or two sentences.)
(a) The values you obtain for A across all of the experiments at time t = t1
are the same given you have made all of the measurements at the same time t = t1.
(b) The value you obtain for A in each experiment at t = t2 may be
different relative to the value obtained for A in the same experiment at t = t1.
(c) The expectation value of A is the same at both t = t1 and t = t2.
(d) The values you obtain for A in any of the experiments at either t = t1
or t = t2 must be one of the eigenvalues of its associated Hermitian
operator.
At t = t3 > t2 you measure a second physical observable
B across all of the experiments, i.e. you follow the measurement of A at t = t2
in each experiment with a measurement of B at t = t3 in each
experiment. The commutator of the two Hermitian operators associated with A and
B satisfies [A, B] ≠ 0.
True or False:
(e) The values you obtained for A at t = t2 in any of these
experiments will remain the same at t = t3 given you are measuring a
different physical quantity B, not A.
Now you reset all of the experiments to what they were at t = 0, i.e., you
start all over again with the same initial set of identical experiments. At
time t = t4, you measure A again in all of your experiments.
Moreover, the commutator of the operator associated with A and the Hamiltonian
operator satisfies
[H, A] = 0 .
True or False:
(f) The value you obtain for A in each experiment at t = t4 is the
same as the value you obtained for A in the corresponding experiment at t = t1.
(g) The expectation values of A at t = t and t = t4 are the same.
Solution:
- Concepts:
Fundamental assumptions of quantum mechanics
- Reasoning:
The expectation value of an observable A is constant in time
if A and H commute.
- Details of the calculation:
(a) False. The experiment may have been prepared in a superposition of eigenstates of A.
(b) True. A may not commute with H.
(c) False. In the Schroedinger picture d/dt)<Ψ(t)|A|Ψ(t)> = (iħ)-1<Ψ(t)|[A,
H]|Ψ(t)>, if A does not explicitly depend on time. If [A,H] ≠ 0, then the
expectation value of A is time-dependent.
(d) True. A measurement of an observable always yields an eigenvalue of the
observable.
(e) False. A measurement of B leaves the system in an eigenstates of B. A and
B do not have a common eigenbasis.
(f) False. The experiment may have been prepared in a superposition of
eigenstates of A.
(g) True. See (c). If [A,H] = 0, then the expectation value of A is
time-independent.
Problem 3:
Consider a two-state system governed by the Hamiltonian H with energy eigenstates |E1> and |E2>,
where H|E1> = E1|E1> and H|E2> = E2
|E2>. Consider also two other states,
|x> = (|E1> + |E2>)/√2, and |y> = (|E1>
- |E2>)/√2.
At time t = 0 the system is in state |x>. At what
subsequent times is the probability of finding the system in state |y> the
largest, and what is that probability?
Solution:
- Concepts:
The evolution operator, postulates of QM
- Reasoning:
The evolution operator is a unitary
operator defined through |ψ(t)>
= U(t,t0)|ψ(t0)>.
If H does not explicitly depend on time, then U(t,t0) = exp(-(i/ħ)H(t-t0)).
If |ψ(t0)>
is an eigenfunction of H with eigenvalue E,
then |ψ(t)>
= exp(-(i/ħ)E(t-t0))|ψ(t0)>.
- Details of the calculation:
|ψ(0)> = |x> = (|E1> + |E2>)/√2, |ψ(t)> =
exp(-iHt/ħ)|ψ(0)>
= (exp(-iE1t/ħ)|E1> + exp(-iE2t/ħ)|E2>)/√2.
<y|ψ(t)> = (<E1|ψ(t)> - <E2|ψ(t)>)
/√2 = (exp(-iE1t/ħ) - exp(-iE2t/ħ))/2
= exp(-iE1t/ħ) (1 - exp(-i(E2 - E1)t/ħ))/2.
Probability of finding the system in state |y>:
Py =
|<y|ψ(t)>|2 = (1 - exp(-i(E2 - E1)t/ħ))(1
- exp(+i(E2 - E1)t/ħ))/4
= ½(1 - cos((E2 - E1)t/ħ)).
The probability Py is maximized when cos((E2 - E1)t/ħ)
= -1, or when t = nπħ/(
E2 - E1), n = 1, 3, 5, ... .
Then Py = 1.
Problem 4:
Consider the one-dimensional time-independent Schroedinger equation for some
arbitrary potential U(x). Prove that if a solution ψ(x) has the property that
ψ(x) → 0 as x → ±∞, then the solution must be non-degenerate and therefore real,
apart from a possible overall phase factor.
Hint: Show that the contrary assumption leads to a contradiction.
Solution:
- Concepts:
The time-independent Schroedinger equation
- Reasoning:
If ψ(x) is a solution of the time-independent Schroedinger equation, i.e. of the
eigenfunction of the Hamiltonian H(x),
then
∂2ψ(x)/∂x2 - (2m/ħ2)(E - U(x))ψ(x)
= 0.
- Details of the calculation:
Assume two solutions ψ1(x) and ψ2(x) exist.
The Schroedinger equation tells us that
∂2ψ1(x)/∂x2 - (2m/ħ2)(E - U(x))ψ1(x)
= 0,
∂2ψ2(x)/∂x2 - (2m/ħ2)(E - U(x))ψ2(x)
= 0.
Multiplying the first equation by ψ2(x) and the second equation by ψ1(x)
and subtracting we obtain
ψ2(x)∂2ψ1(x)/∂x2
- ψ1(x)∂2ψ2(x)/∂x2 = 0.
∂/∂x(ψ2(x) ∂ψ1(x)/∂x - ψ1(x) ∂ψ2(x)/∂x)
= ψ2(x) ∂2ψ1(x)/∂x2 - ψ1(x)∂2ψ2(x)/∂x2
= 0.
Therefore ψ2(x) ∂ψ1(x)/∂x - ψ1(x) ∂ψ2(x)/∂x
= C - constant. (Integration)
For bound states the wave function must vanish as x --> ± ∞. Therefore C = 0.
ψ2(x) ∂ψ1(x)/∂x - ψ1(x) ∂ψ2(x)/∂x =
0.
(1/ψ1(x)) ∂ψ1(x)/∂x = (1/ψ2(x)) ∂ψ2(x)/∂x.
∂/∂x(lnψ1(x)) = ∂/∂x(lnψ2(x)).
This integrates to lnψ1(x) = lnψ2(x) + c, ψ2(x)
= γ ψ1(x), where γ = ec.
ψ2(x) can differ from ψ1(x) only by a multiplicative
constant.
If ψ1(x) and ψ2(x) are normalized, then |γ|2 =
1, γ = eiδ, where δ is a real number. If we choose δ = 0, then c = 1
and ψ is a real function.
Problem 5:
A particle in one dimension is in a stationary state.
(a) Show that for any time-independent operator Q, the
expectation or mean value <Q> is independent of time.
(b) Show that the mean value of the particles momentum, <p>, is zero.
Solution
- Concepts:
The postulates of QM
- Reasoning:
Hψ(x.t) = iħ∂ψ(x,t)/∂t. Separation of variable is possible. ψ(x,t) =
ψ(x)exp(-iEt/ħ).
For a stationary state Hψ(x) = Eψ(x). ψ(x) can be chosen to be real.
ψ(±∞) = 0.
[ψ(x) is the solution to a real differential equation.
For any solution one can construct a second solution by taking the complex
conjugate ψ*(x).
ψ(x) and ψ*(x) are either linearly dependent and differ at most by a phase, or
they are linearly independent, in which case you can construct two independent
real-valued solutions ½(ψ(x) + ψ*(x)) = Re(ψ) and ½(ψ(x) - ψ*(x)) = Im(ψ).]
- Details of the calculation:
(a) <Q(t)> = ∫-∞∞ dx ψ*(x,t) Q ψ(x,t) = ∫-∞∞
dx ψ(x)exp(iEt/ħ) Q ψ(x)exp(-iEt/ħ)
= ∫-∞∞ dx ψ(x)Q ψ(x) = <Q(0)>, since Q does not act on
time.
(b) <p> = -iħ∫-∞∞ dx ψ*(x) ∂ψ(x)/∂x = -iħ∫-∞∞
dx ψ(x) ∂ψ(x)/∂x, since ψ(x) is real.
<p> = -½iħ∫-∞∞ dx ∂ψ2(x)/∂x = -½iħψ2(x)|-∞∞
= 0.
or
[H, x] = -iħp/m
<ψ|p|ψ> ∝ <ψ|[H, x]|ψ> = <ψ|(Hx - xH) |ψ>
= E<ψ|x|ψ> - E<ψ|x|ψ> = 0.