Physics 5403 Homework 6 solved

Description

1 Scattering in 1D

Suppose a plane wave hx|φi = e
ikx/
√
2π coming from the left is scattered by a finite range
potential in 1D.

a) Compute the Green’s function for a free particle in 1D, and show that it gives
G
(+)(x, x0
) = 1
2ik e
ik|x−x
0
|
.

b) In the case of an attractive potential
V (x) = −γ
~
2
2m
δ(x)
with γ > 0, solve the Lipmann-Schwinger equation and compute the reflection and transmission amplitudes of the scattered wave.

c) Compute the energy of the bound state in the well. Show that it corresponds to a
resonance in the transmission and reflection amplitudes.

2 Hydrogen atom

The scattering potential of an incoming electron due to a hydrogen atom at the origin is
V (x, x
0
) = −
e
2
|x|
+
e
2
|x − x0
|
,
where e is the electron charge, x is the coordinate of the incoming electron, and x
0
the coordinate of the electron in the orbital hx
0
|n, `, mi = Rn,l(r
0
)Y
`
m(θ
0
, ϕ0
) centered at the origin.

Show that in the first Born approximation, the elastic differential scattering cross section of
the incoming electron for a hydrogen atom in the ground state |n, `, mi = |1, 0, 0i is
σ(q) = 4m2
e
4
~
4
1
q
4

1 −
16
(4 + q
2a
2
0
)
2
2
,
where ~q = ~(k − k
0
) is the momentum transfered and a0 is the Bohr radius.

Hint: Calculate
the scattering aplitude for the two particle state |ki|n, `, mi.

3 Lipmann-Schwinger equation

Define the Green’s function operators
G
±
0
(E) ≡ (E − H0 ± i0+)
−1
,
and
G
±(E) ≡ (E − H ± i0+)
−1
,
where H = H0 + V , where V is the perturbation, and H0 the unperturbed Hamiltonian.

a) Show that:
G
±(E) = G
±
0
(E)

1 + V G±(E)

.

b) Using the relation above, show that the equation
|ψ
±
k
i = |ki + G
±(E)V |ki
is equivalent to the Lipmann-Schwinger equation
|ψ
±
k
i = |ki + G
±
0
(E)V |ψ
±
k
i.

c) Show that the scattered modes follow the orthogonality property:
hψ
±
k0|ψ
±
k
i = δ(k − k
0
).
d) If k
0 6= k, show that
hψ
−
k0|V |ki = hk
0
|V |ψ
+
k
i.

4 Identical particles

a) Using the first Born approximation, compute the differential cross section for the scattering
of two identical particles with mass m. Assume that the spin part of the two body wave
function is symmetric under the exchange of the particles.

The two particles interact through
the potential
V (r) = V0 exp[−(|x1 − x2|/a)
2
]
where xi
, i = 1, 2 label their position.

b) Using the definition of the partial wave amplitude:
f` = −
π
k
T`(E),
where
T`(E) = hE, `, m|T|E, `, mi,
is the matrix element of the transmission matrix, show that the phase shift in the first Born
approximation is given by
δ`(k) = −
2
~
2 mk ˆ ∞
0
dr r2
[j`(kr)]2 U(r),
for an arbitrary (but small) potential U(r), where j`(x) is a spherical Bessel function.