1000 Solved Problems in Modern Physics

(Grace) #1

244 3 Quantum Mechanics – II


∇^2 V=− 4 πZe^2 ρ

whereZeis the nuclear charge andρis the charge density.

∴ f(θ)=− 8 πμ

(

Ze^2
q^3 ^2

)∫


0

ρ(r)sin(qr)rdr

=

(

2 μZe^2
q^2 ^2

)(

4 π
q

)∫∞

0

ρ(r)sin(qr)rdr

The quantity

(

4 π
q

)∫


0 ρ(r)sin(qr)rdris known as the form factor.

3.118 f(θ)=


(


2 μ
q^2

)∫∞

0

V(r)sin(qr)rdr (1)

Substituting,

V(r)=

z 1 z 2 e^2
r

e−ar (2)

Wherea= 1 /ro, (1) becomes

f(θ)=−

(

2 μz 1 z 2 e^2
q^2

)∫∞

0

e−arsin(qr)dr

=

− 2 μz 1 z 2 e^2
q^2

q
q^2 +a^2

=

− 2 μz 1 z 2 e^2
^2

(

q^2 + 1 /r 02

) (3)

But the momentum transfer

q= 2 ksin

(

θ
2

)

(4)

The differential cross-section

σ(θ)=|f(θ)|^2 =

4 μ^2 z^21 z^22 e^4
^4

(

4 k^2 sin^2 (θ/2)+ 1 /r^20

) 2 (5)

The general angular distribution of scattered particles is reminiscent of
Rutherford scattering. However forθ<θ 0 , where
sin(θo/2)≈ 1 / 2 kro (6)
the curve does not rise indefinitely but tends to flatten out because when
qro 1, the angular dependence ofσ(θ) is damped out resulting in the
flattening of the curve. The angleθomay be considered as the limiting angle
below which the Rutherford scattering is inoperative because of the shielding
of the atomic nucleus by the electron cloud.
Rutherford scattering is derived from (5) by lettingro→∞, in which case
the scattering would occur from a bare nucleus. The screening potential (2)
now reduces to Coulomb potential. Furthermore, writingk=p=μv,(5)
becomes
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