Wave vector in spherical coordinates

Question

I understand the wave vector for plane waves in Cartesian coordinates. Along the direction of propagation of wave, $$k = sqrt{k_x^2+k_y^2+k_z^2} = frac{2pi}{lambda}$$
If $(k_x, k_y, k_z) neq 0$, this would mean we can find troughs and crests moving along $(x,y,z)$ directions respectively. The dot product in wave equation in Cartesian coordinates, $vec{dr}=(dx,dy,dz)$ would be $$vec{k}cdotvec{dr} = k_x dx + k_y dy + k_z dz$$
What would the interpretation be in case of spherical coordinates? Can we still have wave vector, $k = (k_{r},k_{theta},k_{phi})$ along $(r,theta,phi)$ directions such that  $$k = sqrt{k_r^2+k_{theta}^2+k_{phi}^2} = frac{2pi}{lambda}$$
If $(k_{r},k_{theta},k_{phi}) neq 0$, would this mean we can find troughs and crests moving along $(r,theta,phi)$ directions respectively. Is the following dot product in wave equation in spherical coordinates, $vec{dr}=(dr,dtheta,dphi)$ correct? $$vec{k}cdotvec{dr}= k_{r}dr + k_{theta}rdtheta + k_{phi}rsintheta dphi$$

Emilio Pisanty · Answer

As a general rule, having a wave vector $vec k$ implies that you have a travelling wave, i.e. one which transports momentum and energy.
This is particularly relevant to part of your question,

would this mean we can find troughs and crests moving along $(r,theta,phi)$ directions respectively,

because you cannot have a travelling wave along the $theta$ direction $-$ the energy would accumulate at the north axis and you'd need a source along the south. A travelling wave along the $phi$ axis is less of a problem (you can have energy circling around indefinitely) but it's still a problem (you would have energy circling around indefinitely).
That said, the general answer to your question is: yes. The way to get at it is to rephrase the Cartesian wavevector into saying that we want to solve the wave equation,
$$
nabla^2 f = frac{1}{c^2}partial_t^2 f,
$$
first by separating out $f(mathbf r,t)=f(mathbf r)e^{-iomega t}$ into a space- and time-dependent parts, and then handling the resulting Helmholtz equation for the spatial part by using Cartesian coordinates,
$$
frac{partial^2 f}{partial x^2} + frac{partial^2 f}{partial y^2} + frac{partial^2 f}{partial z^2} = k^2 f,
$$
and using separation of variables. Here the wavenumber arises as a straight definition $k^2=omega^2/c^2$, and once you solve the ODE of each individual coordinate into individual exponentials, the result can be folded back into $f(mathbf r)=e^{imathbf kcdot mathbf r}$, with a wavevector $mathbf k$ whose norm coincides with $k$.
Now, if you want the wave behaviour of $f(mathbf r)$ to go along the spherical coordinate surfaces, then you do the same, but now you address the Helmholtz equation
$$
nabla^2 f = k^2 f
$$
by expressing $nabla^2$ in spherical coordinates, and you separate the variables as $f(mathbf r)=R(r)Theta(theta)Phi(phi)$. The resulting procedure is standard, so I won't reproduce it here (try e.g. Jackson's Classical Electrodynamics for a thorough solution, or any book on advanced mathematical methods for physics). The upshot is that:

The solution for the angular variables is that $Theta(theta)Phi(phi) = Y_{lm}(theta,phi)$ must be one of the family of spherical harmonics, which are functions which "wave" exclusively in the angular directions, with nodes along the $theta=rm const$ and $phi=rm const$ directions. However, because of the problems mentioned at the start, particularly in the $theta$ direction, they are not travelling waves $-$ they are standing waves.
Moreover, the spherical-harmonics solutions do not have any associated "wave vector". Instead, the description of the wave moves over to the two indices $l$ and $m$, which describe the total number of nodes and how they're split into the azimuth and altitude directions.

For the radial variable, the Helmholtz equation becomes the spherical Bessel equation,
$$
r^{2}{frac {d^{2}R}{dr^{2}}}+2r{frac {dR}{dr}}+left(k^2r^{2}-l(l+1)right)R=0,
$$
and its solutions are the spherical Bessel functions. As a general rule, all of these are spherical waves, with crests and troughs along the radial direction, but there's several different types:

The spherical Bessel functions of the first kind, $j_l(kr)$, describe standing waves, and are regular at the origin.
The spherical Bessel functions of the second kind, $y_l(kr)$, describe standing waves, but they have a singularity at the origin, so they can only be used if the origin is not part of the region of interest.
The spherical Hankel functions, $h_l^{pm}(kr)$, describe travelling waves, with a source (or sink) at the origin, where they have a singularity.

Eli · Answer

begin{align*}
&text{with}
vec{R}&=r,left[ begin {array}{c} cos left( phi right) sin left( theta
 right)   sin left( theta right) sin left(
phi right)   cos left( theta right)
end {array} right]

vec{dR}&=left[ begin {array}{c} cos left( phi right) sin left( theta
 right)   sin left( theta right) sin left(
phi right)   cos left( theta right)
end {array} right]
,dr&+left[ begin {array}{c} -rsin left( theta right) sin left(
phi right)   rcos left( phi right) sin
 left( theta right)   0end {array} right]
,dphi&+ left[ begin {array}{c} rcos left( phi right) cos left( theta
 right)   rcos left( theta right) sin left(
phi right)   -rsin left( theta right)
end {array} right]
,dtheta
end{align*}
thus $~vec{dR}ne (dr~,dphi~,dtheta)$

Wave vector in spherical coordinates

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