Atmospheric diffraction

Not to be confused with Atmospheric refraction.
Sunrise animation (fifteen seconds/frame) with diffraction rings caused by water droplets and only visible when the sun is near the horizon

Atmospheric diffraction is manifested in the following principal ways:

However, if the object has a diameter greater than the acoustic wavelength, a 'sound shadow' is cast behind the object where the sound is inaudible. (Note: some sound may be propagated through the object depending on material).

Optical atmospheric diffraction

Solar diffraction ring

When light travels through thin clouds made up of nearly uniform sized water or aerosol droplets or ice crystals, diffraction or bending of light occurs as the light is diffracted by the edges of the particles. This degree of bending of light depends on the frequency (color) of light and the size of the particles. The result is a pattern of rings, which seem to emanate from the sun, moon, planet or other astronomical object. The most distinct part of this pattern is a central, nearly white disk. This appears like an atmospheric Airy disc but is not actually an Airy disk. It is distinct from rainbows and halos, which are mainly caused by refraction.

Lunar diffraction ring

The photo (left) shows a diffraction ring around the rising sun. A veil of aerosol caused this phenomenon, and the effect dramatically disappeared, when the sun rose high enough so that the pattern was not presented to the observer at the Earth's surface. This phenomena is sometimes called the corona effect, not to be confused with the solar corona.

On the right is a one tenth second shutter speed exposure showing presenting an overexposed full moon. The moon is seen through thin vaporous clouds which glow with a white disk surrounded by an illuminated red ring. A longer exposure would show more faint colors beyond the outside red ring.

Another form of atmospheric diffraction or bending of light occurs when light moves through fine layers of particulate dust trapped primarily in the middle layers of the troposphere. This effect differs from water based atmospheric diffraction because the dust material is opaque whereas water allows light to pass through it. This has the effect of tinting the light the color of the dust particles. This tinting can vary from red to yellow depending on geographical location. the other primary difference is that dust based diffraction acts as a magnifier instead of creating a distinct halo. This occurs because the opaque matter does not share the lensing properties of water. The effect is to make an object visibly larger while being more indistinct as the dust distorts the image. This effect varies largely based on the amount and type of dust in the atmosphere.

Radio wave propagation in the ionosphere

The ionosphere is a layer of partially ionized gases high above the majority of the Earth's atmosphere; these gases are ionized by cosmic rays originating on the sun. When radio waves travel into this zone, which commences about 80 kilometers above the earth, they experience diffraction in a manner similar to the visible light phenomenon described above.[1] In this case some of the electromagnetic energy is bent in a large arc, such that it can return to the Earth's surface at a very distant point (on the order of hundreds of kilometers from the broadcast source. More remarkably some of this radio wave energy bounces off the Earth's surface and reaches the ionosphere for a second time, at a distance even farther away than the first time. Consequently a high powered transmitter can effectively broadcast over 1000 kilometers by using multiple "skips" off of the ionosphere.

An exotic variant of this radio wave propagation has been examined to show that, theoretically, the ionospheric bounce could be greatly exaggerated if a high powered spherical acoustical wave were created in the ionosphere from a source on earth.[2]

Acoustical diffraction near the Earth's surface

In the case of sound waves travelling near the Earth's surface, the waves are diffracted or bent as they traverse by a geometric edge, such as a wall or building. This phenomenon leads to a very important practical effect: that we can hear "around corners". Because of the frequencies involved considerable amount of the sound energy (on the order of ten percent) actually travels into this would be sound "shadow zone". Visible light exhibits a similar effect, but, due to its much higher frequency, only a minute amount of light energy travels around a corner.

A useful branch of acoustics dealing with the design of noise barriers examines this acoustical diffraction phenomenon in quantitative detail to calculate the optimum height and placement of a soundwall or berm adjacent to a highway.

This phenomenon is also inherent in calculating the sound levels from aircraft noise, so that an accurate determination of topographic features may be understood. In that way one can produce sound level isopleths, or contour maps, which faithfully depict outcomes over variable terrain.

Bibliography

  1. Leonid M. Brekhovskikh, Waves in Layered Media Academic Press, New York, 1960)
  2. Michael Hogan, Ionospheric Diffraction of VHF Radio Waves, ESL Inc., Palo Alto, California, IR-26 22 May 1967

See also

External links

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