Mathematical Methods for Physics and Engineering : A Comprehensive Guide

18.6 SPHERICAL BESSEL FUNCTIONS

whereis an integer. This equation looks very much like Bessel’s equation and

can in fact be reduced to it by writingR(r)=r−^1 /^2 S(r), in which caseS(r)then

satisfies

r^2 S′′+rS′+

[

k^2 r^2 −

(

+^12

) 2 ]

S=0.

On making the change of variablex=krand lettingy(x)=S(kr), we obtain

x^2 y′′+xy′+[x^2 −(+^12 )^2 ]y=0,

where the primes now denoted/dx.ThisisBessel’sequationoforder+^12

and has as its solutionsy(x)=J+1/ 2 (x)andY+1/ 2 (x). The general solution of

(18.101) can therefore be written

R(r)=r−^1 /^2 [c 1 J+1/ 2 (kr)+c 2 Y+1/ 2 (kr)],

wherec 1 andc 2 are constants that may be determined from the boundary

conditions on the solution. In particular, for solutions that are finite at the origin

we requirec 2 =0.

The functionsx−^1 /^2 J+1/ 2 (x)andx−^1 /^2 Y+1/ 2 (x), when suitably normalised, are

calledspherical Bessel functionsof the first and second kind, respectively, and are

denoted as follows:

j(x)=

√

π

2 x

J+1/ 2 (x), (18.102)

n(x)=

√

π

2 x

Y+1/ 2 (x). (18.103)

For integer, we also note thatY+1/ 2 (x)=(−1)+1J−− 1 / 2 (x), as discussed in

section 18.5.2. Moreover, in section 18.5.1, we noted that Bessel functions of the

first kind,Jν(x), of half-integer order are expressible in closed form in terms of

trigonometric functions. Thus, all spherical Bessel functions of both the first and

second kinds may be expressed in such a form. In particular, using the results of

the worked example in section 18.5.1, we find that

j 0 (x)=

sinx

x

, (18.104)

n 0 (x)=−

cosx

x

. (18.105)

Expressions for higher-order spherical Bessel functions are most easily obtained

by using the recurrence relations for Bessel functions.