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HANKEL FUNCTIONS

Many authors prefer to introduce the Hankel functions by means of integral representations and then to use them to define the Neumann function Nν(z). An outline of this approach is given at the end of this section.

Definitions

Because we have already obtained the Neumann function by more elementary (and less powerful) techniques, we may use it to define the Hankel functions Hν(1) (x ) and Hν(2) (x ):

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET(11.85)

and

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET (11.86)

This is exactly analogous to taking

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET

Since the Hankel functions are linear combinations (with constant coefficients) of Jν and Nν , they satisfy the same recurrence relations (Eqs. (11.10) and (11.12))

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET


Example 11.4.1 CYLINDRICAL TRAVELING WAVES 

As an illustration of the use of Hankel functions, consider a two-dimensional wave problem similar to the vibrating circular membrane of Exercise 11.1.25. Now imagine that the waves are generated at r = 0 and move outward to infinity. We replace our standing waves by traveling ones. The differential equation remains the same, but the boundary conditions change. We now demand that for large r the wave behave like

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET              (11.97)

to describe an outgoing wave. As before, k is the wave number. This assumes, for simplicity, that there is no azimuthal dependence, that is, no angular momentum, or m = 0. In Sections 7.3 and 11.6, H(1)(kr ) is shown to have the asymptotic behavior (for r →∞)

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET         (11.98)

This boundary condition at infinity then determines our wave solution as

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET               (11.99)

This solution diverges as r → 0, which is the behavior to be expected with a source at the origin.

The choice of a two-dimensional wave problem to illustrate the Hankel function H0(1) (z) is not accidental. Bessel functions may appear in a variety of ways, such as in the separation of conical coordinates. However, they enter most commonly in the radial equations from the separation of variables in the Helmholtz equation in cylindrical and in spherical polar coordinates. We have taken a degenerate form of cylindrical coordinates for this illustration. Had we used spherical polar coordinates (spherical waves), we should have encountered index Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET ,n an integer. 

 

Contour Integral Representation of the Hankel Functions 

The integral representation (Schlaefli integral)

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET

may easily be established as a Cauchy integral for ν = n, an integer (by recognizing that the numerator is the generating function (Eq. (11.1)) and integrating around the origin).
If ν is not an integer, the integrand is not single-valued and a cut line is needed in our complex plane. Choosing the negative real axis as the cut line and using the contour shown in Fig. 11.7, we can extend Eq. (11.100) to nonintegral ν . Substituting Eq. (11.100) into Bessel’s ODE, we can represent the combined integrand by an exact differential that vanishes as t →∞e±iπ .
We now deform the contour so that it approaches the origin along the positive real axis, as shown in Fig. 11.8. For x> 0, this particular approach guarantees that the exact differential mentioned will vanish as t → 0 because of the e−x/2t → 0 factor. Hence each of the separate portions (∞ e−iπ to 0) and (0 to ∞ e ) is a solution of Bessel’s equation. We define

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET

These expressions are particularly convenient because they may be handled by the method of steepest descents. Hν(1) (x ) has a saddle point at t =+i , whereas Hν(2) (x ) has a saddle point at t =−i .

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET

FIGURE 11.7 Bessel function contour.

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET

The problem of relating Eqs. (11.101) and (11.102) to our earlier definition of the Hankel function (Eqs. (11.85) and (11.86)) remains. Since Eqs. (11.100) to (11.102) combined yield

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET                 (11.103)

by inspection, we need only show that

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET              (11.104)

This may be accomplished by the following steps :

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET

Integral representations have appeared before: Eq. (8.35) for Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET and various representations of Jν (z). With these integral representations of the Hankel functions, it is perhaps appropriate to ask why we are interested in integral representations. There are at least four reasons. The first is simply aesthetic appeal. Second, the integral representations help to distinguish between two linearly independent solutions. In Fig. 11.6, the contours C1 and C2 cross different saddle points. For the Legendre functions the contour for P(z) (Fig. 12.11) and that for Qn (z) encircle different singular points.

Third, the integral representations facilitate manipulations, analysis, and the development of relations among the various special functions. Fourth, and probably most important of all, the integral representations are extremely useful in developing asymptotic expansions. One approach, the method of steepest descents. A second approach, the direct expansion of an integral representation for the modified Bessel function Kν (z). This same technique may be used to obtain asymptotic expansions of the confluent hypergeometric functions M and U .
In conclusion, the Hankel functions are introduced here for the following reasons:

  • As analogs of e±ix they are useful for describing traveling waves.
  • They offer an alternate (contour integral) and a rather elegant definition of Bessel functions.
  • Hν(1) is used to define the modified Bessel function Kν.


 

MODIFIED BESSEL FUNCTIONS, Iν (x ) AND Kν (x )

The Helmholtz equation,

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET

The analog to Eq. (11.22a) is

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET

The Helmholtz equation may be transformed into the diffusion equation by the transformation k → ik . Similarly, k → ik changes Eq. (11.22a) into Eq. (11.109) and shows that

Yν (kρ ) = Zν (i kρ ).

The solutions of Eq. (11.109) are Bessel functions of imaginary argument. To obtain a solution that is regular at the origin, we take Zν as the regular Bessel function Jν .Itis customary (and convenient) to choose the normalization so that

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET               (11.110)

(Here the variable kρ is being replaced by x for simplicity.) The extra i −ν normalization cancels the i ν from each term and leaves Iν (x ) real. Often this is written as

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET                 (11.111)

I0 and I1 are shown in Fig. 11.10.

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET

Series Form 

In terms of infinite series this is equivalent to removing the (−1)s sign in Eq. (11.5) and writing

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET

 Recurrence Relations 

The recurrence relations satisfied by Iν (x ) may be developed from the series expansions, but it is perhaps easier to work from the existing recurrence relations for Jν (x ). Let us replace x by −ix and rewrite Eq. (11.110) as

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET            (11.114)

Then Eq. (11.10) becomes

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET

Replacing x by ix , we have a recurrence relation for Iν (x ),

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET        (11.115)

Equation (11.12) transforms to

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET             (11.116)

These are the recurrence relations. It is worth emphasizing that although two recurrence relations, Eqs. (11.115) and (11.116) or  specify the second-order ODE, the converse is not true. The ODE does not uniquely fix the recurrence relations. Equations (11.115) and (11.116)  provide an example.
From Eq. (11.113) it is seen that we have but one independent solution when ν is an integer, exactly as in the Bessel functions Jν . The choice of a second, independent solution of Eq. (11.108) is essentially a matter of convenience. The second solution given here is selected on the basis of its asymptotic behavior — as shown in the next section. The confusion of choice and notation for this solution is perhaps greater than anywhere else in this field.  Many authors choose to define a second solution in terms of the Hankel function Hν(1) (x ) by

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET

analogous to Eq. (11.60) for Nν (x ). The choice of Eq. (11.117) as a definition is somewhat unfortunate in that the function Kν (x ) does not satisfy the same recurrence relations as Iν (x ) . zTo avoid this annoyance, other authors21 have included an additional factor of cos νπ . This permits Kν to satisfy the same recurrence relations as Iν , but it has the disadvantage of making Kν = 0forBessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET

The series expansion of Kν (x ) follows directly from the series form of Hν(1) (i x ).The lowest-order terms are (cf. Eqs. (11.61) and (11.62))

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET

Because the modified Bessel function Iν is related to the Bessel function Jν , much as sinh is related to sine, Iν and the second solution Kν are sometimes referred to as hyperbolic Bessel functions. K0 and K1 are shown in Fig. 11.10.
I0 (x ) and K0 (x ) have the integral representations

Bessel`s Special Function - 3 | Physics for IIT JAM, UGC - NET, CSIR NET

Equation (11.120) may be derived from Eq. (11.30) for J0 (x ) or may be taken as  ν = 0. The integral representation of K0 , Eq. (11.121), is a Fourier transform and may best be derived with Fourier transforms, Chapter 15, or with Green’s functions. A variety of other forms of integral representations (including ν ≠ 0) appear in the exercises. These integral representations are useful in developing asymptotic forms  and in connection with Fourier transforms.
To put the modified Bessel functions Iν (x ) and Kν (x ) in proper perspective, we introduce them here because:

  •  These functions are solutions of the frequently encountered modified Bessel equation.
  • They are needed for specific physical problems, such as diffusion problems.
  • Kν (x ) provides a Green’s function.
  • Kν (x ) leads to a convenient determination of asymptotic behavior .
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