Physical Chemistry Third Edition

(C. Jardin) #1

17.2 The Relative Schrödinger Equation. Angular Momentum 731


Substitution ofΘ(θ)Φ(φ) into Eq. (17.2-7) followed by division byΘ(θ)Φ(φ) and
multiplication by sin^2 (θ) gives

sin(θ)
Θ

d

(

sin(θ)



)

+

1

Φ

d^2 Φ
dφ^2

−Ksin^2 (θ) (17.2-9)

The variablesθandφare now separated.

TheΦFunctions


The last term on the left-hand side of Eq. (17.2-9) depends only onφand the other
terms depend only onθ. The independent variableθcan be held fixed whileφranges,
so the last term must be a constant function ofφ. We denote the constant by−m^2. With
this choice,mwill turn out to be a real integer. Multiplication byΦgives the equation

d^2 Φ
dφ^2

−m^2 Φ (17.2-10)

Except for the symbols used Eq. (17.2-10) is the same as several equations already
encountered. Its general solution can be written in the form of Eq. (15.3-6)

ΦCcos(mφ)+Dsin(mφ) (17.2-11)

or in the form of Eq. (15.3-26)

ΦAeimφ+Be−imφ (17.2-12)

whereA,B,C, andDare constants.
We always assume that a wave function must be continuous at all locations. The
variableφranges from 0 to 2πwhen measured in radians. Sinceφ0 andφ 2 π
refer to the same location for given values ofrandθ, we must require that

Φ(0)Φ(2π) (17.2-13)

This condition is satisfied only ifmis real and equal to an integer.

Exercise 17.2
Show thatmis real and equal to an integer ifΦ(0)Φ(2π).

There are two versions of theΦfunction. The first version ofΦis an eigenfunction
of̂Lz, which is given in spherical polar coordinates by Eq. (16.3-20):

̂Lzh ̄
i


∂φ

(17.2-14)

We operate on the version ofΦin Eq. (17.2-12) witĥLz:

̂LzΦh ̄
i

(

imAeimφ−imBe−imφ

)

(17.2-15)
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