1000 Solved Problems in Modern Physics

218 3 Quantum Mechanics – II

NowLzg(φ)=−i∂∂φg=mg(φ)
Thus the z-component of angular momentum is quantized with eigen
value.
3.81 One can do similar calculations forLxandLyas in Problem 3.80 and obtain
Lx
i

=sinφ

∂

∂θ

+cotθcosφ

∂

∂φ

Ly

i

=−cosφ

∂

∂θ

+cotθsinφ

∂

∂φ

3.82 UsingL^2 =L^2 x+L^2 y+L^2 z, the commutator with total angular momentum
squared can be evaluated

[L^2 ,Lz]=

[

L^2 x+L^2 y+L^2 z,Lz

]

=

[

L^2 x+L^2 y,Lz

]

=Lx[Lx,Lz]+[Lx,Lz]Lx+Ly

[

Ly,Lz

]

+

[

Ly,Lz

]

Ly (1)

=−iLxLy−iLyLx+iLyLx+iLxLy= 0

Similarly

[

L^2 ,Lx

]

=[L^2 ,Ly]=[L^2 ,L]= 0

3.83 L^2 =L^2 x+L^2 y+L^2 z
Using the expressions forLx,LyandLzfrom problem (3.81)

L^2

(i)^2

=

(

sinφ

∂

∂θ

+cotθcosφ

∂

∂φ

)(

sinφ

∂

∂θ

+cotθcosφ

∂

∂φ

)

+

(

−cosφ

∂

∂θ

+cotθsinφ

∂

∂φ

)(

−cosφ

∂

∂θ

+cotθsinφ

∂

∂φ

)

+

(

−

∂

∂φ

)(

−

∂

∂φ

)

=sin^2 φ

∂^2

∂θ^2

+cot^2 θcos^2 φ

∂^2

∂φ^2

−sinφcosφcosec^2 θ

∂

∂φ

+cos^2 φcotθ

∂

∂θ

+cos^2 φ

∂^2

∂θ^2

+cot^2 θsin^2 φ

∂^2

∂φ^2

+sinφcosφcosec^2 θ

∂

∂φ

+sin^2 φcotθ

∂

∂θ

+

∂^2

∂φ^2

The cross terms get cancelled and the expression is reduced to

∂^2

∂θ^2

+

1

sin^2 θ

∂^2

∂φ^2

+cotθ

∂

∂θ

∇^2 ψ=

1

r^2

∂

∂r

(

r^2

∂ψ

∂r

)

+

1

r^2 sinθ

∂

∂θ

(

sinθ

∂ψ

∂θ

)

+

1

r^2 sin^2 θ

∂^2 ψ

∂φ^2