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Transcript
Columbia University
Department of Physics
QUALIFYING EXAMINATION
Wednesday, January 13, 2016
3:10PM to 5:10PM
Modern Physics
Section 4. Relativity and Applied Quantum Mechanics
Two hours are permitted for the completion of this section of the examination. Choose 4 problems
out of the 5 included in this section. (You will not earn extra credit by doing an additional problem).
Apportion your time carefully.
Use separate answer booklet(s) for each question. Clearly mark on the answer booklet(s) which
question you are answering (e.g., Section 4 (Relativity and Applied QM), Question 2, etc.).
Do NOT write your name on your answer booklets. Instead, clearly indicate your Exam Letter
Code.
You may refer to the single handwritten note sheet on 8 12 ” × 11” paper (double-sided) you have
prepared on Modern Physics. The note sheet cannot leave the exam room once the exam has begun.
This note sheet must be handed in at the end of today’s exam. Please include your Exam Letter
Code on your note sheet. No other extraneous papers or books are permitted.
Simple calculators are permitted. However, the use of calculators for storing and/or recovering
formulae or constants is NOT permitted.
Questions should be directed to the proctor.
Good Luck!
Section 4
Page 1 of 6
1. Consider the first relativistic correction, H1 , in the Hamiltonian for the one dimensional harmonic oscillator.
p2
p2 1
1
H = H0 + H1 =
+ mω2 x2 −
2m 2
2mc2 2m
!2
(1)
Evalulate the first order shift in the ground state energy due to H1 .
Recall that the ground state wave function is given by
U0 (x) =
Section 4
mω 1/4
π~
mωx2
exp −
2~
"
#
(2)
Page 2 of 6
2. An asteroid is on a collision course with a space station located 5000 light-minutes from Earth.
The asteroid is moving away from the Earth toward the space station at a speed of 3/5c along
a trajectory which is a straight line connecting Earth and the space station. To save the station,
NASA launches a missle from Earth at 4/5c. When the missile is launched, NASA determines
that the asteroid is 400 light-minutes from Earth.
(a) How many minutes should NASA set on a timer located on the missle so that it will
explode just as it catches up to the asteroid? (In all parts of this problem, ignore subtleties
having to do with acceleration.)
(b) A few weeks later, another asteroid is on a similar collision course with the space station,
travelling again at 3/5c. NASA decides to send another missile to destroy it, but this time
they want the missile to pass the asteroid and explode only when according to sensors on
the missile, the missile is 350 light minutes beyond the asteroid. In this scenario, how
many minutes should NASA set on the missile’s timer?
(c) From the perspective of the missile’s frame of reference, how far away is the asteroid
when the missile is launched?
Section 4
Page 3 of 6
3. A thin plate with surface rest-mass density Σ0 [g/cm2 ] is surrounded by uniform dust at rest
with mass density ρ [g/cm3 ]. At time t = 0 the plate is set in motion along its normal with
initial Lorentz factor γ(0) = γ0 . The moving plate collides inelastically with the dust particles
(which stick to its surface) and gradually decelerates.
Find the evolution of its Lorentz factor γ(t). If γ0 1, at what time γ(t) = γ0 /2?
Section 4
Page 4 of 6
4. A one-dimensional non-relativistic particle interacts with the potential
V(x) = λ
~2
δ(x),
2m
(3)
where λ is a constant and the prefactor is factored out to simplify the algebra.
(a) Calculate the reflection and transmission coefficients (probabilities) as a function of the
incident particle wavenumber k.
(b) Calculate the scattering and bound states for λ < 0. Show that there is a single bound
state, and that it is orthogonal to the scattering states.
Section 4
Page 5 of 6
5. Consider a hydrogen atom. The spin-orbit interaction at radius r is written as:
Hso =
e2 ~ ~
S · L,
2m2 c2 r3
(4)
where S~ is the spin of the electron and ~L.
(a) Describe in words the origin of the spin-orbit interaction.
(b) Construct the basis of wave functions that diagonalize Hso .
(c) Obtain the spin-orbit interaction energies for hydrogen in the state with radial quantum
number n=2. You may express your answer in terms of the expectation values h1/r3 i of
the hydrogen atom states (you do not need to calculate these expectation values explicitly).
Section 4
Page 6 of 6
Section 4-1
Mueller
UNI Here:
1. Relativistic Harmonic Oscillator: Mueller
Consider the first relativistic correction, H1 , in the Hamiltonian for the one dimensional
harmonic oscillator.
2 2
p2
1
1
p
2 2
H = H0 + H1 =
+ mω x −
(1)
2
2m 2
2mc 2m
Evalulate the first order shift in the ground state energy due to H1 .
Recall that the ground state wave function is given by
mω 1/4
mωx2
U0 (x) =
exp −
π~
2~
(2)
Solution: It is convenient to write
1
H1 = −
2mc2
1
H0 − mω 2 x2
2
2
(3)
Then, the energy shift in the ground state is given by,
∆E = hU0 |H1 |U0 i
Z ∞
mω 1/2
1
mωx2
dx
= −
exp −
2mc2 −∞
π~
~
1
− mω 2 x2 (4)
2
hU0 |H0 |U0 i=E0 =~ω/2
H0
2 2
Z
1 mω 1/2 ∞
mωx2
~ω
mωx2
=−
dx exp −
1−
2mc2 π~
~
2
~
−∞
2
Z ∞
~2 ω 2 mω 1/2
mωx2
mωx2
=−
2
dx exp −
1−
8mc2 π~
~
~
0
Now switch variables to y = mωx2 /~, dy = (2mω/~)xdx = 2(mω/~)1/2 y 1/2 dx,
Z ∞
~2 ω 2
dy
2
∆E = − 1/2 2
exp[−y]
1
−
2y
+
y
8π mc 0 y 1/2
Z ∞
~2 ω 2
= − 1/2 2
dy exp[−y] y −1/2 − 2y 1/2 + y 3/2
8π mc 0
~2 ω 2
~2 ω 2
1 3
= − 1/2 2 [Γ(1/2) − 2Γ(3/2) + Γ(5/2)] = − 1/2 2 Γ(1/2)
1−2 +
8π mc
8π mc √π
2 4
= −~ω
2
3 ~ω
32 mc2
!2
(5)
(6)
(7)
(8)
(9)
(10)
Section 4-2
Greene
UNI Here:
2. Relativity: Greene
An asteroid is on a collision course with a space station located 5000 light-minutes
from Earth. The asteroid is moving away from the Earth toward the space station at
a speed of 3/5c along a trajectory which is a straight line connecting Earth and the
space station. To save the station, NASA launches a missle from Earth at 4/5c. When
the missile is launched, NASA determines that the asteroid is 400 light-minutes from
Earth.
a) How many minutes should NASA set on a timer located on the missle so that it
will explode just as it catches up to the asteroid? (In all parts of this problem, ignore
subtleties having to do with acceleration.)
b) A few weeks later, another asteroid is on a similar collision course with the space
station, travelling again at 3/5c. NASA decides to send another missile to destroy
it, but this time they want the missile to pass the asteroid and explode only when
according to sensors on the missile, the missile is 350 light minutes beyond the asteroid.
In this scenario, how many minutes should NASA set on the missile’s timer?
c) From the perspective of the missile’s frame of reference, how far away is the asteroid
when the missile is launched?
Solution.
Work in units with c = 1 light-minute/minute.
a) The time to catch asteroid ∆t on the Earth clock is given by 54 ∆t = 400 + 35 ∆t
and so ∆t = 2000. Because the missile is moving, its clock ticks off slow due to time
dilation, and so the engineers set it to 2000/γ = 2000/( 35 ) = 1200 minutes, where
γ = (1 − [4/5]2 )−1/2 = 5/3.
5
b) Relative to the missile, the asteroid has a speed of β = ( 45 − 35 )/(1 − 54 35 ) = 13
. Thus,
for the missile to travel 350 light-minutes beyond the asteroid, from its perspective,
5
it will take an additional 350/ 13
= 910 minutes, beyond the 1200 minutes required to
reach the asteroid, for a total of 2110 minutes.
c) Consider the primed frame to be that of the missile, which is moving with β = 4/5
(γ = 5/3) with respect to the lab frame. Using the Lorentz transformation, the
asteroid’s trajectory in the Earth’s frame (t, 400 + 35 t) intersects the x0 axis (t0 = 0)
for the missile at time t = β(400 + (3/5)t), or t = 8000/13, i.e. when the missile is at
80
(t, 45 t) = 13
(100, 125). In the missile’s coordinates, this location is (t0 = 0, x0 = 400 15
),
13
15
and hence from the missile’s perspective, the asteroid is at a distance of 400 13 lightminutes when it launches.
3
Section 4-3
Beloborodov
UNI Here:
3. Relativity: Beloborodov To the typesetter: in the text below please replace ”inelastically with the dust particles” with ”inelastically with the dust particles (which
stick to its surface)”
Relativity:
A thin plate with surface rest-mass density ⌃0 [g/cm2 ] is surrounded by uniform dust at rest with mass
density ⇢ [g/cm3 ]. At time t = 0 the plate is set in motion along its normal with initial Lorentz factor
(0) = 0 . The moving plate collides inelastically with the dust particles and gradually decelerates.
Find the evolution of its Lorentz factor (t). If 0
1, at what time (t) = 0 /2?
Solution:
Let x(t) be the displacement of the plate; its velocity is v = dx/dt. The column density of the swept-up
dust is ⌃d (t) = ⇢ x(t). Conservation of energy and momentum gives
0 ⌃0
+ ⌃d ,
(1)
v ⌃ = v 0 0 ⌃0 .
(2)
⌃=
Note that ⌃ > ⌃0 + ⌃d , as the growing inertial mass of the plate includes heat produced in the inelastic
collisions. To get rid of the unknown ⌃ divide the two equations; then one finds
v 0 0 ⌃0
0 ⌃0 + ⌃ d
v=
This equation can be solved for x(t). Introducing x? ⌘
x2
x+
= v0 t
2x?
and hence
v(t) = v0
where t? = x? /v0 .
=
0 /2
✓
2t
1+
t?
)
◆ 1/2
0 ⌃0 /⇢,
x(t) = x?
,
v 0 0 ⌃0
.
0 ⌃0 + ⇢x
dx
=
dt
or
(t) =
corresponds to t = 3t? /(2
2
0
0
one obtains
s
✓
(3)
!
2v0 t
1+
x?
1 ,
1 + 2t/t?
1 + 2 02 t/t?
◆1/2
(4)
,
(5)
8), which gives t ⇡ 3⌃0 /2 0 ⇢c when
0
1.
General:
Electric current I is circulating along an ideally conducting thin hoop of mass M and radius R. The
~ 0 that is perpendicular
hoop is placed in infinite vacuum space and set in rotation with angular velocity ⌦
to the hoop axis. How will its angular velocity evolve with time?
Solution:
~ and hence its second time
The magnetic dipole moment of the hoop µ = ⇡R2 I/c rotates about ⌦
2
~¨ /3c3 , and hence
derivative is |µ
~¨ | = ⌦2 µ. This generates magneto-dipole radiation with power Ė = 2µ
the hoop kinetic energy E = M R2 ⌦2 /4 is gradually4 decreasing,
d
dt
M R 2 ⌦2
4
!
=
2
3c3
⌦2 ⇡R2 I
c
!2
)
⌦(t) =
1
8⇡ 2 R2 I 2 t
+
3M c5
⌦20
! 2
.
Section 4-4
Metzger
UNI Here:
4. Scattering/Bound States - Metzger
A one-dimensional non-relativistic particle interacts with the potential
V (x) = λ
~2
δ(x),
2m
(11)
where λ is a constant and the prefactor is factored out to simplify the algebra.
(a) Calculate the reflection and transmission coefficients (probabilities) as a function
of the incident particle wavenumber k.
(b) Calculate the scattering and bound states for λ < 0. Show that there is a single
bound state, and that it is orthogonal to the scattering states.
Solution.
(a) The Schrodinger equation reads
−
~ 2 d2 ψ
d2
+
V
(x)ψ
=
Eψ
⇒
−
+ λδ(x)ψ(x) = k 2 ψ(x)
2
2
2m dx
dx
(12)
The solution is
ψ(x) = eikx + Re−ikx , x < 0
(13)
ψ(x) = T eikx , x > 0,
(14)
where E = ~2 k 2 /2m is the incident energy.
Boundary conditions: (1) ψ(x) is continuous at x = 0,
⇒1+R=T
(15)
while (2) integrating the Schrodinger equation across x = 0 gives
dψ
dψ
|x− −
|x+ + λψ(0) = 0
dx
dx
(16)
⇒ ik(1 − R) + λ(1 + R) = ikT
(17)
Solving for the amplitudes,
R=
−iλ
2k
,T =
2k + iλ
2k + iλ
(18)
and the resulting transmission probabilities
|R|2 =
λ2
,
4k 2 + λ2
5
|T |2 =
4k 2
4k 2 + λ2
(19)
Section 4-4
Metzger
UNI Here:
(b) The scattering states have already been calculated since part (a) did not depend on
the sign of λ. The bound states have wave functions which are exponentially damped,
ψB (x) = Aeκx , x < 0,
(20)
ψB (x) = Be−κx , x > 0,
(21)
where the energy is E = −~2 κ2 /2m. The same boundary conditions as before lead to
A = B, κA + λA = −κB
(22)
2κ = −λ
(23)
with solution
This is only a sensible solution for κ > 0, i.e. for λ < 0. A = B are fixed by normalizing
the bound state,
√ −κ|x|
κe
(24)
B (x) =
The bound state is unique, since there is a single solution.
The overlap between the bound state ψB with a scattering state ψk of wavenumber k:
Z 0
Z ∞
Z ∞
√ κx
√ −κx
√ R−T
1
∗
−ikx
−ikx
dxψB (x) ψk (x) =
κe (1+Re
)+
κe (T e
)= κ
+
=0
κ − ik κ
−∞
0
−∞
(25)
where in the final equality we have used equation (17)
6
Section 4-5
Pinczuk
UNI Here:
5. Spin-Orbit Interaction in Hydrogen Atom - Pinczuk
Consider a hydrogen atom. The spin-orbit interaction at radius r is written as:
Hso =
e2
~ · L,
~
S
2m2 c2 r3
(26)
~ is the spin of the electron and L.
~
where S
(a) Describe in words the origin of the spin-orbit interaction.
(b) Construct the basis of wave functions that diagonalize Hso .
(c) Obtain the spin-orbit interaction energies for hydrogen in the state with radial
quantum number n=2. You may express your answer in terms of the expectation values
h1/r3 i of the hydrogen atom states (you do not need to calculate these expectation
values explicitly).
Solution.
(a) In the rest frame of the electron the proton is moving with velocity ~v , that produces
~ ∝ L.
~ The coupling of this field to the intrinsic magnetic moment
a magnetic field B
~ is the spin-orbit interaction Hso . In fact, this simple-minded picture only
from S
accounts for half of the effect described by equation (26). The electron’s motion in the
proton’s electric field alone will give a spin-orbit Hamiltonian
Hso =
ge e2 ~ ~
S·L
2m2 c2 r3
(27)
which is ge ∼ 2 times larger than that in eq. (26). However, equation (27) actually
describes the motion of the spin relative to a reference system that, because of its
circular acceleration, is actually rotating in the laboratory. The Hamiltonian that
describes both effects has a factor (ge − 1) ∼ 1, which is the correct expression given
in equation (26).
(b) Rewrite the spin-orbit interaction as
e2
e2
~
~
Hso =
S·L=
(J 2 − L2 − S 2 ),
2
2
3
2
2
3
2m c r
4m c r
(28)
where J~ is the total angular momentum. The states with quantum numbers J, L, and
S make this Hamiltonian diagonal. These states can be written as |j, m, l, si, where
m are the quantum number associated with the z components of the total angular
momentum.
In this basis the matrix elements of Hso are given by
#
"
~2 e2
−3
hHso i =
hr inl j(j + 1) − l(l + 1) − s(s + 1)
(29)
2m2 c2 r3
=3
4
7
Section 4-5
Pinczuk
UNI Here:
(c) For n = 2 the allowed states of l are 0 or 1. The allowed values of j are 1 ± 21 .
The value j = 1/2 is obtained from l = 0, 1. There are two terms.
The value j = 3/2 is obtained from l = 1 only (one term here).
There are also two matrix elements:
hr−3 i2,0 ≡ A0
(30)
hr−3 i2,1 ≡ A1
(31)
and
The spin-orbit interaction energies are obtained with equations (29) and (31).
8