1000 Solved Problems in Modern Physics

(Romina) #1

224 3 Quantum Mechanics – II


whereF(r)=rf(r)

Lzψ 1 =−i


∂φ

(cosφ+isinφ)sinθF(r)

=−i(−sinφ+icosφ)sinθF(r)
=(cosφ+isinφ)sinθF(r)
=ψ 1
Thusψ 1 is the eigen state and the eigen value is
ψ 2 =zf(r)=rcosθf(r)

Lzψ 2 =−i


∂φ

(rcosθf(r))= 0

The eigen value is zero.
ψ 3 =(x−iy)f(r)=rsinθ(cosφ−isinφ)f(r)
=(cosφ−isinφ)sinθF(r)

Lzψ 3 =−i


∂φ

(cosφ−isinφ)sinθF(r)

=−i(−sinφ−icosφ)sinθF(r)
=i(sinφ+icosφ)sinθF(r)
=−(cosφ−isinφ)sinθF(r)=−ψ 3
Thusψ 3 is an eigen state and the eigen value is−.

3.89 (a)Lz=−i∂
∂φ


Lzψ=−i


∂φ

Af(r)sinθcosθeiφ

=(i)(−iAf(r)sinθ cosθeiφ)
=Af(r)sinθ cosθeiφ
=ψ
Therefore, thez-component of the angular momentum is.
(b)L^2 =−^2

{

∂^2
∂θ^2 +cotθ


∂θ+

(

1
sin^2 θ

)

∂^2
∂φ^2

}

Expressions forLzandL^2 are derived in Problems 3.80 and 3.83.

L^2 ψ=−^2

{
∂^2
∂θ^2
+cotθ


∂θ
+

(
1
sin^2 θ

)
·

∂^2
∂φ^2

}
Af(r)sinθcosθeiφ

=−^2 Af(r)eiφ

{
−4sinθcosθ+cotθ(cos^2 θ−sin^2 θ)−
sinθcosθ
sin^2 θ

}

= 6 ^2 Af(r)sinθcosθeiφ
= 6 ^2 ψ
ThusL^2 = 6 ^2
ButL^2 =l(l+1). Thereforel= 2
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