18.7 LAGUERRE FUNCTIONS
it has a regular singularity atx= 0 and an essential singularity atx=∞.The
parameterνis a given real number, although it nearly always takes an integer
value in physical applications. The Laguerre equation appears in the description
of the wavefunction of the hydrogen atom. Any solution of (18.107) is called a
Laguerre function.
Since the pointx= 0 is a regular singularity, we may find at least one solutionin the form of a Frobenius series (see section 16.3):
y(x)=∑∞m=0amxm+σ. (18.108)Substituting this series into (18.107) and dividing through byxσ−^1 ,weobtain
∑∞m=0[(m+σ)(m+σ−1) + (1−x)(m+σ)+νx]amxm=0.
(18.109)Settingx= 0, so that only them= 0 term remains, we obtain the indicial
equationσ^2 = 0, which trivially hasσ= 0 as its repeated root. Thus, Laguerre’s
equation has only one solution of the form (18.108), and it, in fact, reduces to
a simple power series. Substitutingσ= 0 into (18.109) and demanding that the
coefficient ofxm+1vanishes, we obtain the recurrence relation
am+1=m−ν
(m+1)^2am.As mentioned above, in nearly all physical applications, the parameterνtakesinteger values. Therefore, ifν=n,wherenis a non-negative integer, we see that
an+1=an+2=···= 0, and so our solution to Laguerre’s equation is a polynomial
of ordern. It is conventional to choosea 0 = 1, so that the solution is given by
Ln(x)=(−1)n
n![
xn−n^2
1!xn−^1 +n^2 (n−1)^2
2!xn−^2 −···+(−1)nn!]
(18.110)=∑nm=0(−1)mn!
(m!)^2 (n−m)!xm, (18.111)whereLn(x) is called thenthLaguerre polynomial. We note in particular that
Ln(0) = 1. The first few Laguerre polynomials are given by
L 0 (x)=1, 3!L 3 (x)=−x^3 +9x^2 − 18 x+6,L 1 (x)=−x+1, 4!L 4 (x)=x^4 − 16 x^3 +72x^2 − 96 x+24,2!L 2 (x)=x^2 − 4 x+2, 5!L 5 (x)=−x^5 +25x^4 − 200 x^3 + 600x^2 − 600 x+ 120.The functionsL 0 (x),L 1 (x),L 2 (x)andL 3 (x) are plotted in figure 18.7.