In the mathematical study of rotational symmetry, the zonal spherical harmonics are special spherical harmonics that are invariant under the rotation through a particular fixed axis. The

zonal spherical function In mathematics, a zonal spherical function or often just spherical function is a function on a locally compact group ''G'' with compact subgroup ''K'' (often a maximal compact subgroup) that arises as the matrix coefficient of a ''K''-invariant vect ...

s are a broad extension of the notion of zonal spherical harmonics to allow for a more general

symmetry group In group theory, the symmetry group of a geometric object is the group of all transformations under which the object is invariant, endowed with the group operation of composition. Such a transformation is an invertible mapping of the ambient ...

. On the two-dimensional sphere, the unique zonal spherical harmonic of degree ℓ invariant under rotations fixing the north pole is represented in spherical coordinates by

Z^(\theta,\phi) = P_\ell(\cos\theta)

where is a Legendre polynomial of degree . The general zonal spherical harmonic of degree ℓ is denoted by

Z^_(\mathbf)

, where x is a point on the sphere representing the fixed axis, and y is the variable of the function. This can be obtained by rotation of the basic zonal harmonic

Z^(\theta,\phi).

In ''n''-dimensional Euclidean space, zonal spherical harmonics are defined as follows. Let x be a point on the (''n''−1)-sphere. Define

Z^_

to be the dual representation of the linear functional

P\mapsto P(\mathbf)

in the finite-dimensional

Hilbert space In mathematics, Hilbert spaces (named after David Hilbert) allow generalizing the methods of linear algebra and calculus from (finite-dimensional) Euclidean vector spaces to spaces that may be infinite-dimensional. Hilbert spaces arise natural ...

H_ℓ of spherical harmonics of degree ℓ. In other words, the following reproducing property holds:

Y(\mathbf) = \int_ Z^_(\mathbf)Y(\mathbf)\,d\Omega(y)

for all . The integral is taken with respect to the invariant probability measure.

Relationship with harmonic potentials

The zonal harmonics appear naturally as coefficients of the Poisson kernel for the unit ball in R^''n'': for x and y unit vectors,

\frac\frac = \sum_^\infty r^k Z^_(\mathbf),

where

\omega_

is the surface area of the (n-1)-dimensional sphere. They are also related to the

Newton kernel In mathematics, the Newtonian potential or Newton potential is an operator in vector calculus that acts as the inverse to the negative Laplacian, on functions that are smooth and decay rapidly enough at infinity. As such, it is a fundamental object ...

via

\frac = \sum_^\infty c_ \fracZ_^(\mathbf/, \mathbf, )

where and the constants are given by

c_ = \frac\frac.

The coefficients of the Taylor series of the Newton kernel (with suitable normalization) are precisely the ultraspherical polynomials. Thus, the zonal spherical harmonics can be expressed as follows. If , then

Z^_(\mathbf) = \fracC_\ell^(\mathbf\cdot\mathbf)

where are the constants above and

C_\ell^

is the ultraspherical polynomial of degree ℓ.

Properties

*The zonal spherical harmonics are rotationally invariant, meaning that

Z^_(R\mathbf) = Z^_(\mathbf)

for every orthogonal transformation ''R''. Conversely, any function on that is a spherical harmonic in ''y'' for each fixed ''x'', and that satisfies this invariance property, is a constant multiple of the degree zonal harmonic. *If ''Y''₁, ..., ''Y''_''d'' is an orthonormal basis of , then

Z^_(\mathbf) = \sum_^d Y_k(\mathbf)\overline.

*Evaluating at gives

Z^_(\mathbf) = \omega_^ \dim \mathbf_\ell.

References

* {{citation, last1=Stein, first1=Elias, authorlink1=Elias Stein, first2=Guido, last2=Weiss, authorlink2=Guido Weiss, title=Introduction to Fourier Analysis on Euclidean Spaces, publisher=Princeton University Press, year=1971, isbn=978-0-691-08078-9, location=Princeton, N.J., url-access=registration, url=https://archive.org/details/introductiontofo0000stei. Rotational symmetry Special hypergeometric functions