What does the electric field of a spherical wave look like?

In summary: But on the other hand, real physical emitters (like light bulbs) typically emit waves that look a bit more like ripples on a pond surface than a plane wave.
  • #1
user299792458
18
0
What does the electric field of a "spherical wave" look like?

You often hear about spherical light waves. For example, something like a light bulb is said to emit waves which are more or less spherical. Let's assume this light bulb is perfectrly round and emits in all directions (as opposed to a real light bulb, which has that metal thing at the bottom and doesn't emit light in that direction). Supposedly, the light bulb I'm describing would emit spherical waves. But what I don't understand is, what would the electric field of these waves look like? I can understand spherically symmetric sound waves, but light is a transverse wave. The electric field vector has to be perpendicular to the direction that the wave is travelling. It seems to me that, in this case, the electric field lines would have to resemble lines of latitude or longitude (on a globe) or something else, but the electric field can not be spherically symmetric. So what does the solution of Maxwell's equations look like for this spherical wave? What do we mean when we say that this wave is spherically symmetric? I can't find this in my physics books and I also tried searching Google with no luck.
 
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  • #2
Well there are two different aspectes to your question.

1) a light bulb like object (assuming it didn't have any
piece of it to block the light in any direction) would emit
what's called isotropically in its power density vs. solid
angle. It is an incoherent source emitting
actually relatively few photons per time interval, but
because it's a 'random' thermal symmetric isotropic
emitter, it has a uniform probability of emitting energy
packets in any given direction. So, on a long term
average basis, there'd be a spherically symmetric
light flux with equal illuminance everywhere on any
larger enclosing sphere. The individual photons /
wave packets that are a result of blackbody radiation
from the hot surface, though, would not necessarily be
without a specific direction and non-isotropic concentration
of their fields. In that respect it wouldn't be so
different than something like the sun, composed of a
large number of atoms / ions / particles, each of which
emits radiation essentially randomly and
relatively independently of the others, but over all it'd
be equiprobably directed over a long time.


2) A hypothetical coherent radiator that's either an
infinitely tiny point source or some hypothetical extended
source that's coherent might be modeled as emitting
spherical wavefronts in the manner you describe, and
quite simply such wave fronts would 'look like' a plane
wave except with curvature to cover a sphere. If you
conformally mapped a plant to a sphere or in analogy
a line to a circle (and ended up with something like
ripples on a pond surface -- transverse waving up and
down but circularly symmetric wave-fronts), you'd have
the idealized version of the coherent spherical emitter.
The individual waves would still be transverse E/M but
that doesn't preclude them from being smooth plane
waves, and since a plane is equivalent to a sphere you
could say the same for spherical waves. However I
have no information that any real point source or
extended emitter is truly an coherent isotropoc emitter
when examined over short time-scales and levels of
individual photons being emitted. Perhaps I'm wrong
about that, QED isn't my specialty, though I know a bit
about classical and quantum E/M theory.
I've also heard it argued that, in fact, that truly spherical
wavefronts cannot exist physically since though they could
be permitted by the Maxwell equations in some senses,
they'd reportedly necessarily violate
divergence-free conditions in other aspects required for
the Maxwell equations and physicality. I don't recall the
exact argument / mathematics / author, but I could
probably easily find a citation on request. I believe that
author was criticizing the Maxwell's equations themselves
in some respects, and that argument was just a small
point in an overall thesis. The more important thing
from a practical standpoint is that real physical
quantum-isotropic emitters may not really exist on the
quantum level, though you can certainly have
isotropic probability emitters that are quantum or
macroscopic in average.

If I'm wrong about any of this, I'd love to hear more
details about the situation from people that know more
about coherent quantum electrodynamic statistics or
topological aspects of Maxwell's theory.
 
  • #3
oops I made lots of typos in a rush; please forgive that;
I'll let them stand for now since I have to attend to other
matters.
 
  • #4
Wow. That was quite a response, xez!

Here's an attempt at a simpler explanation: the wave solution applies to the magnitude of the E/M wave, that is, if you look at the time and spatial dependence of the magnitudes of the electric and magnetic field vectors, they will fit the form of a nice spherical wave. When you ask about the directions of those vectors, then you're getting into details of the emission process, and yes, I believe you can't have a truly spherically symmetric solution (as mathematicians put it, "you can't comb a hairy tennis ball"). Generally, however, the directions of the vectors are randomized (incoherent), so you really can think just in terms of the amplitudes (vector magnitudes) of the fields, being symmetric.
 
  • #5
belliott4488 said:
(as mathematicians put it, "you can't comb a hairy tennis ball").
I've never heard of that theorem (just looked it up in Wikipedia), but that's basically what I was thinking, that you can't have a truly spherically symmetric EM wave. It seems that even the magnitude of the electric field vectors can't be completely spherically symmetric? So I guess it varies randomly and when you average it over time you get spherical symmetry? Is that the case?
 
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  • #6
xez said:
emitting actually relatively few photons per time interval
In what sense?
 
  • #7
cesiumfrog said:
In what sense?

Avogadro's number vs. Planck's constant
e.g. the number of atoms in a macroscopic object versus
the total number of photons emitted per second.

Also in the sense of the "photon density" of photons per
square meter per second at a modestly extended distance
from the emitter.

Let's see:
[eV/J] = 1/1.60217733*10^-19 = 6.24150636*10^18.

So if a 100W incandescent bulb was 10% efficient at
emitting visible light photons, that'd be 10 Joules/second
of photons from the bulb.

If the average photon energy emitted is 2eV, that'd be
3.12*10^18 * 2eV average photons / Joule, and

3.12*10^19 photons per second total, which over a
10m * 10m * 10m room = 10^12 square mm would
be 3.12*10^7 photons per second per square millimeter
which is already rather sparse and certainly an easily
physically countable discrete rate of them.

Even looking at fairly bright stars or other astronomical
objects in a fairly sizable telescope you end up getting
relatively small total numbers of photons per second
collected in your instrument, and the 'image' being more
of a statistical accumulation of lots of discrete values
rather than something that's "present" in any continuous
simultaneous sense.
 
  • #8
user299792458 said:
I've never heard of that theorem (just looked it up in Wikipedia), but that's basically what I was thinking, that you can't have a truly spherically symmetric EM wave. It seems that even the magnitude of the electric field vectors can't be completely spherically symmetric? So I guess it varies randomly and when you average it over time you get spherical symmetry? Is that the case?
Why do say that the magnitude can't be spherically symmetric? The magnitude of a vector field is a scalar field, and there's no reason why that can't be spherically symmetric, is there? Think of spherical shells whose color varies periodically.
 
  • #9
The problem, belliott, is (vector) polarisation (which breaks the spherical symmetry). Of course, for a light bulb (not a coherent source) you might be right.
 
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  • #10
The light emitted by a light bulb isn't a single simple wave, spherical or otherwise, because a light bulb isn't a single simple source. It contains bazillions of sources (individual atoms) radiating in short bursts at random times and random polarizations.

I don't know for sure what form the wave emitted from an individual atom is, but I suspect it might be like the wave emitted by an oscillating electric dipole. I couldn't find (with a quick Google search) a diagram illustrating both direction and magnitude for either the electric or magnetic field from such a dipole, but maybe someone else knows where to find one. As I recall, the electric field amplitude and direction both vary with the angle from the dipole axis.

However, for something like a light bulb, the individual sources' dipole axes are oriented randomly with respect to each other, so the net electric field amplitude is spherically symmetric for practical purposes, and the direction of the field at any given point varies rapidly and randomly with time.
 
  • #11
cesiumfrog said:
The problem, belliott, is (vector) polarisation (which breaks the spherical symmetry). Of course, for a light bulb (not a coherent source) you might be right.
Yes, I know. That's why I earlier said that the approximation of a spherical wave is applied only to the magnitude. If you want to get into the vector components of the field, you have to get into the details of the production mechanism. If this is a coherent field, such as a polarized wave, then it's not spherically symmetric, but it's likely not coming from a point source, either.

I don't think anyone really speaks of spherically symmetric wave fronts when the specific directions of the vector fields are relevant. You tend to speak of plane waves in such cases.
 
  • #12
Would you normally speak at all of wave fronts when the source is incoherent?
 
  • #13
cesiumfrog said:
Would you normally speak at all of wave fronts when the source is incoherent?
Um ... well, I thought that's what the spherical waves were. :confused: We already established that a coherent wave couldn't be spherically symmetric, so any spherical wave makes sense only if you're talking about a wave with unspecified or randomized vector directions. Would you not call that a wave front? Maybe not ...
 
  • #14
belliott4488 said:
Um ... well, I thought that's what the spherical waves were. :confused: We already established that a coherent wave couldn't be spherically symmetric...
A coherent wave can still be unpolarised, and thus spherically symmetric.

Claude.
 
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  • #15
Claude Bile said:
A coherent wave can still be unpolarised, and thus spherically symmetric.

Claude.
Yes, you're right, of course. I've been speaking too loosely - I'll just be quiet, now.:redface:
 
  • #16
I didn't mean to sound harsh!

Claude.
 
  • #17
Claude Bile said:
A coherent wave can still be unpolarised, and thus spherically symmetric.

Claude.
Isn't a spherically symmetric transverse wave inconsistent with the "hairy ball" theorem that has been mentioned here?
 
  • #18
For a spherical, unpolarised wavefront, each point on the spherical wavefront is indistinguishable from any other and any orientation (direction) is indistinguishable from any other. I would say that spherical symmetry is preserved in this case.

Claude.
 

1. What is a spherical wave?

A spherical wave is a type of electromagnetic wave that radiates outward in all directions from a point source. It is characterized by its spherical shape and the fact that the electric field is perpendicular to the direction of propagation.

2. How is the electric field of a spherical wave different from other types of electromagnetic waves?

The electric field of a spherical wave is unique in that it decreases in strength as it propagates outward from the source. Other types of electromagnetic waves, such as plane waves, maintain a constant electric field strength as they propagate through space.

3. What factors affect the shape of the electric field in a spherical wave?

The shape of the electric field in a spherical wave is primarily affected by the distance from the source and the frequency of the wave. As the distance from the source increases, the electric field strength decreases. Higher frequencies also result in stronger electric fields closer to the source.

4. Can the electric field of a spherical wave be manipulated?

Yes, the electric field of a spherical wave can be manipulated by changing the properties of the source, such as its frequency or amplitude. Additionally, external factors such as the presence of other objects or materials can also affect the shape and strength of the electric field.

5. What practical applications does understanding the electric field of a spherical wave have?

Understanding the electric field of a spherical wave is crucial in many fields, including telecommunications, radar technology, and medical imaging. By manipulating and analyzing the electric field, we can gather information about the source and its surroundings, allowing us to make important observations and measurements.

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