Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(lu) #1

19.2 PHYSICAL EXAMPLES OF OPERATORS


Consider firstL^2 |ψ′〉, recalling thatL^2 commutes with bothLxandLyand hence


withU:


L^2 |ψ′〉=L^2 U|ψ〉=UL^2 |ψ〉=Ua|ψ〉=aU|ψ〉=a|ψ′〉.

Thus,|ψ′〉is also an eigenstate ofL^2 , corresponding to the same eigenvalue as


|ψ〉. Now consider the action ofLz:


Lz|ψ′〉=LzU|ψ〉

=(ULz+U)|ψ〉,using[Lz,U]=U,

=Ub|ψ〉+U|ψ〉

=(b+)U|ψ〉

=(b+)|ψ′〉.

Thus,|ψ′〉is also an eigenstate ofLz, but with eigenvalueb+.


In summary, the effect ofUacting upon|ψ〉is to produce a new state that

has the same eigenvalue forL^2 and is still an eigenstate ofLz, though with that


eigenvalue increased by. An exactly analogous calculation shows that the effect


ofDacting upon|ψ〉is to produce another new state, one that also has the same


eigenvalue forL^2 and is also still an eigenstate ofLz, though with the eigenvalue


decreased byin this case. For these reasons,UandDare usually known as


ladderoperators.


It is clear that, by starting from any arbitrary eigenstate and repeatedly applying

eitherUorD, we could generate a series of eigenstates, all of which have the


eigenvalueaforL^2 , but increment in theirLzeigenvalues by±. However, we


also have the physical requirement that, for real values of thez-component, its


square cannot exceed the square of the total angular momentum, i.e.b^2 ≤a. Thus


bhas a maximum valuecthat satisfies


c^2 ≤a but (c+)^2 >a;

let the corresponding eigenstate be|ψu〉withLz|ψu〉=c|ψu〉. Now it is still true


that


LzU|ψu〉=(c+)U|ψu〉,

and, to make this compatible with the physical constraint, we must have that


U|ψu〉is the zero ket vector|∅〉. Now, using result (19.31), we have


DU|ψu〉=(L^2 −L^2 z−Lz)|ψu〉,

⇒ 0 |∅〉=D|∅〉=(a^2 −c^2 −c)|ψu〉,

⇒ a=c(c+).

This gives the relationship betweenaandc. We now establish the possible forms


forc.


If we start with eigenstate|ψu〉, which has the highest eigenvaluecforLz,and
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