Mathematical Methods for Physics and Engineering : A Comprehensive Guide

QUANTUM OPERATORS

The proof, which makes repeated use of

[

A, A†

]

=
, is as follows:

Am(A†)m=Am−^1 AA†(A†)m−^1

=Am−^1 (A†A+
)(A†)m−^1

=Am−^1 A†A(A†)m−^1 +
Am−^1 (A†)m−^1

=Am−^1 A†(A†A+
)(A†)m−^2 +
Am−^1 (A†)m−^1

=Am−^1 (A†)^2 A(A†)m−^2 +Am−^1 A†
(A†)m−^2 +
Am−^1 (A†)m−^1

=Am−^1 (A†)^2 (A†A+
)(A†)m−^3 +2
Am−^1 (A†)m−^1

..

.

=Am−^1 (A†)mA+m
Am−^1 (A†)m−^1.

Now we take the expectation values in the ground state| 0 〉of both sides of

this operator equation and note that the first term on the RHS is zero since it

contains the termA| 0 〉. The non-vanishing terms are

〈 0 |Am(A†)m| 0 〉=m
〈 0 |Am−^1 (A†)m−^1 | 0 〉.

The LHS is the square of the norm of (A†)m| 0 〉, and, from equation (19.45), it is

equal to

|d 0 |^2 |d 1 |^2 ···|dm− 1 |^2 〈 0 | 0 〉.

Similarly, the RHS is equal to

m
|d 0 |^2 |d 1 |^2 ···|dm− 2 |^2 〈 0 | 0 〉.

It follows that|dm− 1 |^2 =m
and, taking all coefficients as real,dm=

√

(m+1)
.

Thus the correctly normalised state of energy (n+^12 )
, obtained by repeated

application ofA†to the ground state, is given by

|n〉=

(A†)n

(n!
n)^1 /^2

| 0 〉. (19.48)

To evaluate thecn, we note that, from the commutator ofAandA†,
[
A, A†

]

|n〉=AA†|n〉−A†A|n〉

|n〉=

√

(n+1)
A|n+1〉−cnA†|n− 1 〉

=

√

(n+1)
cn+1|n〉−cn

√

n
|n〉,

=

√

(n+1)
cn+1−cn

√

n
,

which has the obvious solutioncn=

√

n
. To summarise:

cn=

√

n
 and dn=

√

(n+1)
. (19.49)

We end this chapter with another worked example. This one illustrates how

the operator formalism that we have developed can be used to obtain results