Assignment 8
Problem 1:
A particle in some unspecified potential is in the initial normalized state
ψ(x) = a x e-x/b, x ≥ 0,
ψ(x) = 0, x < 0.
(a) Where are you most likely to find the particle if you were to measure
its position?
(b) What is the probability of finding the particle in the region x > 0?
Solution:
- Concepts:
The fundamental assumptions of quantum mechanics
- Reasoning:
The wave function
ψ(x) is interpreted as a probability amplitude of the particles presence.
Here ψ(x) is given. If it can be normalized, then |ψ(x)|2 is
the probability density.
The position x for which |ψ(x)|2 has a maximum is the most
likely position.
- Details of the calculation:
(a) |ψ(x)|2 = a2 x2 e-2x/b.
d|ψ(x)|2/dx = 2a2 x e-2x/b - 2(a2/b)
x2 e-2x/b = 0.
1 - x/b = 0, x = b.
If you were to measure the position of the particle you are most likely to find
it in an interval dx about x = b.
(b) The probability of finding the particle in the region x > 0 is 1.
Problem 2:
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 3:
For a certain system, the operator corresponding to the physical quantity A
does not commute with the Hamiltonian.
It has eigenvalues a1 and a2, corresponding to the
eigenfunctions
Φ1 = 2-1/2(u1 + u2)
and Φ2 = 2-1/2(u1 - u2),
where u1 and u2 are normalized eigenfunctions of the
Hamiltonian with eigenvalues E1 and E2, respectively.
If the system is in the state ψ = Φ1 at time t = 0, calculate the time
evolution of the expectation value of A.
Solution:
- Concepts:
Fundamental assumptions of QM, the evolution operator
- 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(t) = 2-½[u1exp(-(i/ħ)E1t) + u2exp(-(i/ħ)E2t)]
= ½[Φ1(exp(-iE1t/ħ) + exp(-(i/ħ)E2t)) + Φ2(exp(-iE1t/ħ)
- exp(-(i/ħ)E2t))].
Aψ(t) = ½[a1Φ1(exp(-iE1t/ħ) + exp(-(i/ħ)E2t))
+ a2Φ2(exp(-iE1t/ħ) - exp(-(i/ħ)E2t))].
<A(t)> = <ψ(t)|A|ψ(t)>
= (1/4)[2a1<Φ1|Φ1> + 2a2<Φ2|Φ2>
+ 2a1<Φ1|Φ1>cos((E1 - E2)t/ħ)
- 2a2<Φ2|Φ2>cos((E1 - E2)t/ħ)]
= ½[a1 + a2 + (a1 - a2)cos((E1
- E2)t/ħ)].
Problem 4:
In one dimension, at t = 0 the normalized wave function of a free particle of
mass m in k-space is
Φ(k,0) = Nexp(-k2/(2b2))n with N = 1/(b√π) ½.
Its FWHM in of |Φ(k,0)|2 in k-space is 2√(ln2)b, and <p> = ħ<k>
= 0.
The corresponding wave packet Ψ(x,0) in coordinate space is
Ψ(x,0) = [1/(2π)½][1/(b√π)½] ∫-∞+∞exp(-k2/(2b2))exp(ikx')
dk = (b2/π)¼exp(-x'2b2/2),
with
x' = x - x0, where x0 depends on the choice of the origin of the coordinate
system.
Choose x0 = 0.
The FWHM in of |Ψ(x,0)|2 in coordinate space is 2√(ln2) (1/b)
and <x> = 0.
(a) Find the FWHM in of |Ψ(x,t)|2 an some later time t. Does it
change with time?
(b) Find the FWHM in of |Φ(k,t)|. Does it change with time?
Hint: ∫-∞+∞exp(-a2(x + c)2)dx =
√π/a
Solution:
- Concepts:
Postulates of QM, the Fourier transform
- Reasoning:
We investigate the properties of a Gaussian wave packet representing a
free particle.
- Details of the calculation:
(a) The wave function of a free
particle is a linear superposition of plane waves.
Ψ(x,t) = [1/(2π)½][1/(b√π)½] ∫-∞+∞exp(-k2/(2b2))exp(i(kx
- ωt)) dk.
For a plane wave E = ħω = ħ2k2/(2m), ω = ħk2/(2m).
We can group the k-dependent terms into a perfect square
-k2/(2b2) + i(kx - ħk2t/(2m)) = -k2[1/(2b2)
+ iħt/(2m)] + ikx
= -A(k2 - ikx/A + (ix/2A)2 - (ix/2A)2]
= -A[k - ix/2A]2 - x2/(4A),
where A = 1/(2b2) + iħt/(2m), |A|2 = 1/(4b4) +
ħ2t2/(4m2).
=
∫-∞+∞exp(-A[k - ix/2A]2 - x2/(4A))
dk = exp(-x2/(4A)∫-∞+∞exp(-A[k - ix/2A]2)
dk
= exp(-x2/(4A)√(π/A), using ∫-∞+∞exp(-a(x+b)2)dx
= √(π/a).
Ψ(x,t) = [1/(2π)½][1/(b√π)½] √(π/A) exp(-x2/(4A)).
Ψ(x,t) = (1/(b2π))¼[1/(1/b2 + iħt/m)]½
exp(-x2/(4A)).
|Ψ(x,t)|2 = (1/(b2π))½[(1/(1/b4 + (ħt/m)2)
½ exp(-(b2x2/(1 + (b2ħt/m)2)).
= b/(π(1 + (b2ħt/m)2)-½ exp(-(b2x2/(1
+ (b2ħt/m)2)).
To find the FWHM we use
exp(-(b2x2/(1 + (b2ħt/m)2)) = ½. b2x2
= ln(2)(1 + (b2ħt/m)2),
FWHM = 2√(ln2)(1/b2 + (bħt/m)2)½ = 2√(ln2)
(1/b)(1 + (b2ħt/m)2).
The FWHM of |Ψ(x,t)|2 increases with time.
(b) iħ∂Φ(k,t)/∂t = [p2/(2m)]Φ(k,t) = ħω Φ(k,t).
Φ(k,t) = exp(-iωt)) Φ(k,0). FWHM of |Φ(k,t)| = 2√(ln2)b. It does not change
with time.
Problem 5:
Assume the wave function of a free particle at t = 0 is Ψ(x) = Nx2exp(-x2/2).
Here N is a
normalization constant.
(a) Find N so that ψ(x) is normalized.
(b) The root mean square deviation Δx at t = 0.
(c) What can you say about Ψ(x,t) for t > 0?
Solution:
- Concepts:
The postulates of Quantum Mechanics, the mean value
- Reasoning:
The expression for the mean value of an observable A in the normalized state |ψ>
is
<A> = <ψ|A|ψ>.
- Details of the calculation:
(a) <Ψ|Ψ> = 1. ∫-∞+∞Ψ*(x)Ψ(x) dx
= 1.
N2∫-∞+∞x4
exp(-x2)
dx = N23π½/4 = 1.
N = 2/(9π)¼.[∫0+∞x2n
exp(-x2)
dx = [(1*3*5*...*(2n - 1))/2n+1]π½.]
(b) Δx = (<x2> - <x>2)½.
<x> = 0 from symmetry.
<x2> = ∫-∞+∞Ψ*(x)x2Ψ(x) dx
=
N2∫-∞+∞x6
exp(-x2)dx
= N215π½/8 = 5/2.
Δx = (5/2)½.
(c) We do not know p, but we know that Δp is not zero, Δpmin
≈ ħ/Δx. The wave function is a superposition of plane
waves traveling with different velocities.
Therefore the wave function has to change shape. Δx may increase or
decrease initially, but eventually it will increases, the wave function will
spread out, we will lose position information.