(Rayleigh scattering / Mie scattering / Tyndall
scattering)
In this
section, Feynman discusses the mechanism of Rayleigh scattering, Mie scattering, and Tyndall
scattering. Thus, the section could be titled “Rayleigh scattering, Mie
scattering, and Tyndall scattering.”
1. Rayleigh scattering:
“The
electric field of the incoming beam drives the electrons up and down, and they
radiate because of their acceleration. This scattered radiation combines
to give a beam in the same direction as the incoming beam, but of somewhat
different phase, and this is the origin of the index of refraction (Feynman et
al., 1963, p. 32–6).”
Elastic scattering: “Why is the sky blue?” is commonly explained using the term Rayleigh
scattering by many, but it does not mean they really understand the phenomenon.
On the contrary, Feynman did not mention Rayleigh, but we should acknowledge
his works related to the scattering of light by particles (primarily
nitrogen and oxygen) that are much smaller than the wavelength of the incoming
light. Alternatively, we may use the term elastic scattering because the
wavelength of scattered light is predominantly the same as the incoming light. Importantly, the word scattering
means the absorption of light by a particle and the re-emission of light in
almost all directions due to the oscillation of the particle. In other words,
the electric field of the incoming light oscillates the electrons, and then the
oscillating electrons emit scattered light.
“That
is to say, light which is of higher frequency by, say, a factor of two, is sixteen
times more intensely scattered, which is a quite sizable difference.
This means that blue light, which has about twice the frequency of the reddish
end of the spectrum, is scattered to a far greater extent than red light (Feynman et
al., 1963, p. 32–8).”
Wavelength-dependent scattering: The scattering of light is frequency-dependent
or wavelength-dependent, i.e., the shorter
wavelengths of light (blue and violet) are strongly deflected, whereas the
longer wavelengths (red and orange) are slightly deflected. By using Larmor’s
formula, the power or intensity (I) of the scattered
light is directly proportional to the square of the acceleration (a2) of oscillating
electrons in the field of the incoming light (I µ a2). Furthermore, the acceleration of electrons
is directly proportional to the square of the frequency of the incoming light (a
µ -w2x). In short, one may write I µ a2 µ ω4. Thus, the
intensity of scattered blue light is 1.494 (= 4.9) times more than red light if we assume the wavelength of red light and
blue light are about 700 nm and 470 nm respectively (use l = c/f).
But if
the objects are randomly located, then the total intensity
in any direction is the sum of the intensities that are scattered by
each atom, as we have just discussed (Feynman et al., 1963, p. 32–6).”
Random scattering: Strictly speaking, the objects (or scatterers) are
not only randomly located and the total intensity is not simply the sum of the intensities that
are scattered by each atom. Some may use the term random scattering
because the air molecules are randomly oriented, in random
molecular motion, and there are random microscopic fluctuations that scatter more light in one
direction than another. Historically, Einstein (1910) deduced that
the random thermal motion of the air results in rapid density fluctuations and causes
a similar effect to Rayleigh scattering. It can be described as density fluctuation
scattering because the fluctuations in the density of air would result in fluctuations
in the refractive index of the medium. Based on this model, the refractive index fluctuations
behave like molecular scatterers.
2. Mie scattering:
“We have just explained that
every atom scatters light, and of course the water vapor will scatter light,
too. The mystery is why, when the water is condensed into clouds, does it
scatter such a tremendously greater amount of light? …… But if they
are right next to each other, they necessarily scatter in phase, and they have
a coherent interference which produces an increase in the scattering (Feynman et
al., 1963, p. 32–8).”
Coherent
scattering: Feynman discusses another
mystery pertaining to the scattering of a greater amount of
light by
clouds. It is known as Mie scattering or coherent scattering because the light
waves are coherent in the forward direction due to a lump of particles. Specifically,
Mie scattering is due to aerosol particles, such as water droplets and ice
crystals, but it may include dust, pollen, and smoke that are present in the atmosphere. One
may define Mie scattering as the scattering of light whereby the size of a lump
of “almost in-phase particles” is the same or more than the wavelength of the
incoming light. Although Rayleigh scattering may be considered as the
scattering of light in which the size of the particles is less than 1/10 of the
light’s wavelength, it is a limiting case of Mie scattering.
“So as
we keep increasing the size of the droplets we get more and more scattering,
until such a time that a drop gets about the size of a wavelength, and then the
scattering does not increase anywhere nearly as rapidly as the drop gets bigger
(Feynman et
al., 1963, p. 32–8).”
Multiple scattering: Feynman explains that
there is more scattering of light if the size of the water droplets is
increased till the wavelength of the incoming light. Instead of saying more
and more scattering, we may use the term multiple scattering which depends
on the density of particles, size of scatterers (air molecules or aerosol particles), and path of light. For
example, the paths of sunlight near the horizon (sunrise or sunset) are longer
than the path through the zenith (noon), i.e., we expect more scattering through
longer paths. The color of the sky is not simply blue, but it continues to vary
depending on the Sun’s position, atmospheric conditions, and locations of the
observer (direction of viewing). Multiple scattering of light by water droplets may result in the
appearance of a white cloud or dark cloud depending on the density and height of
the clouds.
3. Tyndall
scattering:
“We use
a solution of sodium thiosulfate (hypo) with sulfuric acid, which precipitates
very fine grains of sulfur. As the sulfur precipitates, the grains first start
very small, and the scattering is a little bluish (Feynman et al., 1963, p. 32–9).”
Feynman ends the lecture using
a demonstration to show the scattering of light by colloidal particles of sulfur. This may be described as Tyndall
scattering experiment (See Fig. 1) that uses a glass tube to simulate the
sky and a light source to represent the Sun. However, Tyndall scattering experiment
does not completely explain how the blue sky varies due to different
meteorological or humidity conditions. In his paper titled On the blue colour of the sky, and on the polarization
of light, Tyndall (1869) writes: “[f]rom the illuminated bluish
cloud, therefore, polarized light was discharged, the direction of maximum
polarization being at right angles to the illuminating beam… (p. 224).” To
acknowledge his findings, Tyndall
scattering may be defined as the lateral scattering of unpolarized light by colloidal
particles whereby maximum polarized light is observable at 90o to
the incoming light.
 |
| Fig. 1 |
So if
the incoming light has an electric field which changes and oscillates in any
direction, which we call unpolarized light, then the light which is coming out at
90o to the beam vibrates in only one direction! (Feynman et
al., 1963, p. 32–9).”
Lateral scattering: We may adopt the term lateral
scattering because the scattered light is perpendicular to the incoming light, however,
it is misleading to say that the light vibrates in only one direction.
Perhaps Feynman could have emphasized that the unpolarized light vibrates in
all planes that are perpendicular to the direction of light propagation and
thus, the scattered light does not vibrate in the same direction as the
incoming light. If the scattered light is moving upward in the vertical
direction, it should be horizontally polarized (See Fig. 2). Additionally,
we observe vertically polarized light if the scattered light emerges in the
horizontal direction. You
should try to connect the direction of lateral scattering of blue light to Brewster’s
angle or Heaviside-Feynman’s formula for the electric field of an accelerated
charge.
 |
| Fig. 2 |
Review Questions:
1. How would you explain the amount of scattering of
light is inversely proportional to the fourth power of its wavelength?
2.
How would you explain the
scattering of light by clouds results in a greater amount of light?
3. How would you explain the scattered light is perpendicular to the incoming light?
The moral of the lesson: The phenomenon of blue sky
is related to Rayleigh scattering that
involves (1) elastic scattering, (2)
wavelength-dependent scattering, (3) random scattering, (4) multiple scattering,
(5) lateral scattering, (6) Sun emits more blue than violet light, and (7) eye-sensitivity
to blue.
References:
1. Brown, P. K., & Wald,
G. (1964). Visual pigments in single rods and cones of the human retina. Science,
144(3614), 45-52.
2. Einstein, A. (1910). The Theory of the Opalescence of Homogeneous Fluids and Liquid Mixtures near the Critical State. Annalen der Physik,
33, 1275-1298.
3. Feynman, R. P., Leighton, R. B., & Sands, M. (1963). The Feynman Lectures on Physics, Vol I: Mainly mechanics, radiation, and heat. Reading, MA: Addison-Wesley.
4. Tyndall, J. (1869). On the blue colour of the sky, and on the polarization of light. Phil. M., (4), 37, 384-394.
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