Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

APPLICATIONS OF COMPLEX VARIABLES


Apply the WKB method to the problem of finding the quantum energy levelsEof a
particle of massmbound in a symmetrical one-dimensional potential wellV(x)that has
only a single minimum. The relevant Schr ̈odinger equation is


^2


2 m

d^2 ψ
dx^2

+V(x)ψ=Eψ.

Relate the problem close to each of the classical ‘turning points’,x=±aat whichE−
V(x)=0, to Stokes’ equation and assume that it is appropriate to use the solutionAi(x)
given in equations (25.52) and (25.53) atx=a. Show that if the general WKB solution in
the ‘classically allowed’ region−a<x<ais to match such Airy solutions atbothturning
points, then
∫a

−a

k(x)dx=(n+^12 )π,

wherek^2 (x)=2m[E−V(x)]/^2 andn=0, 1 , 2 ,....
For a symmetric potentialV(x)=V 0 x^2 s,wheresis a positive integer, show that in this
approximation the energy of thenth level is given byEn=cs(n+^12 )^2 s/(s+1),wherecsis a
constant depending onsbut not uponn.

We start by multiplying the equation through by 2m/^2 ,writing2m[E−V(x)]/^2 ask^2 (x),
and rearranging the equation to read


d^2 ψ
dx^2

+k^2 (x)ψ=0, (25.54)

noting that, withEandV(x) given, the equationE=V(a) determines the value ofaand
thatk(a)=0.
For−a<x<a,wherek^2 (x) is positive, the form of the WKB solutions are given
directly by (25.49) as


ψ±=

C



k(x)

exp

[


±i

∫x
k(u)du

]


.


Just beyond the turning pointx=a,where


E−V(x)=0−V′(a)(x−a)+O[(x−a)^2 ],

equation (25.54) can be approximated by


d^2 ψ
dx^2


2 mV′(a)
^2

(x−a)ψ=0. (25.55)

This, in turn, can be reduced to Stokes’ equation by first settingx−a=μzandψ(x)≡y(z),
so converting it into


1
μ^2

d^2 y
dz^2


2 μmV′(a)
^2

zy=0,

and then choosingμ=[^2 / 2 mV′(a)]^1 /^3. The equation then reads


d^2 y
dz^2

=zy.

Since the solution must be evanescent forx>a,i.e.forz>0, we assume that the
appropriate solution there is Ai(z); this implies that, forzsmall and negative (just inside
the classically allowed region), the solution has the form given by (25.53), namely


A
(−z)^1 /^4

sin

[


2


3


(−z)^3 /^2 +

π
4

]


,

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