1000 Solved Problems in Modern Physics

3.3 Solutions 233

First order correction is

ΔE=

∫

ψ 0 ∗H′ψdτ

∫

ψ 0 ∗ψdτ

∫

ψ 0 ∗H′ψdτ=K^2 W

∫ a

2

0

sin^2

(n 1 πx

a

)

dx

∫a/ 2

0

sin^2

(n 2 πy

a

)

dy

=K^2 W

[

x

2

−

(

a

4 n 1 π

)

sin

(

2 n 1 πx

a

)]a/ 2

0

[

y

2

−

(

a

4 n 2 π

)

sin

(

2 n 2 πy

a

)]a/ 2

0

=

K^2 Wa^2

16

∫a

0

ψ 0 ∗ψ 0 dτ=K^2

∫a

0

∫a

0

sin^2 n 1 πx

a

sin^2 n 2 πy

a

dxdy=

k^2 a^2

4

ThereforeΔE=

K^2 W 0 a^2

16

/

K^2 a^2

4

=

W 0

4

3.3.8 Scattering (Phase Shift Analysis) .....................

3.104 Let the total wave function be

ψ=ψi+ψs (1)

whereψirepresents the incident wave andψsthe scattered wave.

In the absence of potential, the incident plane wave

ψi=Aeikz=eikz (2)

where we have dropped off A to choose unit amplitude.

Assume

ψs=

f(θ)eikr

r

(3)

which ensures inverse square r dependence of the scattered wave from the

scattering centre.

σ(θ)=|f(θ)|^2 (4)

f(θ) being the scattering amplitude.

We can write (1)

ψ=eikrcosθ+

f(θ)eikr

r

(5)

or

fθ=re−ikr(ψ−eikrcosθ)(6)

Ltr→∞

The azimuth angleφhas been omitted inf(θ) as the scattering is assumed

to have azimuthal symmetry. In the absence of potentialψiis the most

general solution of the wave equation.

∇^2 ψi+k^2 ψi=0(7)