Tyndall effect: Difference between revisions
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File:Why_is_the_sky_blue.jpg|Why the sky is blue | |||
File:Iris_close-up.jpg|Close-up of an iris | |||
File:Tyndall_Effect.jpg|Tyndall Effect | |||
File:The_Tyndall_Effect_in_Fog.jpg|The Tyndall Effect in Fog | |||
File:Koloidní_povoha_želatiny.jpg|Koloidní povaha želatiny | |||
File:Lyubertsy,_A._A._Skochinsky_Mining_Institute_-_interior_(16781901395).jpg|Interior of A. A. Skochinsky Mining Institute | |||
File:Lunar_Laser_McDonald_Observatory.jpg|Lunar Laser at McDonald Observatory | |||
File:Internal_Pantheon_Light.JPG|Internal Pantheon Light | |||
File:WaterAndFlourSuspensionLiquid.jpg|Water and Flour Suspension Liquid | |||
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Latest revision as of 12:13, 18 February 2025
Tyndall Effect[edit]
The Tyndall effect, also known as Tyndall scattering, is the scattering of light by particles in a colloid or in very fine suspensions. It is named after the 19th-century scientist John Tyndall, who first studied the phenomenon.
Explanation[edit]
The Tyndall effect occurs when light passes through a medium containing small particles that are large enough to scatter light, but not large enough to settle out of the solution. This scattering causes the path of the light to become visible. The intensity of the scattered light depends on the frequency of the light and the density of the particles.
The effect is more pronounced when the light is blue, which is why the sky appears blue. This is because blue light is scattered more than red light due to its shorter wavelength.
Examples[edit]
In Nature[edit]
The Tyndall effect is responsible for the blue color of the sky. As sunlight passes through the atmosphere, the shorter blue wavelengths are scattered in all directions by the gases and particles in the air. This scattered blue light is what we see when we look up at the sky.
Another example is the blue appearance of some eyes. The structure of the iris scatters light in a way that enhances the blue wavelengths, making the eyes appear blue.
In Everyday Life[edit]
The Tyndall effect can be observed in many everyday situations. For example, when a beam of sunlight enters a dusty room, the path of the light becomes visible due to the scattering of light by the dust particles.
In fog, the Tyndall effect can be seen when car headlights illuminate the tiny water droplets, making the beam of light visible.
Applications[edit]
The Tyndall effect is used in various scientific and industrial applications. It is used to determine the size and density of particles in a colloid. It is also used in laser technology and in the study of aerosols.
Related pages[edit]
References[edit]
- Tyndall, John. On the Blue Colour of the Sky, the Polarization of Skylight, and on the Polarization of Light by Cloudy Matter Generally. Proceedings of the Royal Society of London, 1869.
- Bohren, Craig F., and Donald R. Huffman. Absorption and Scattering of Light by Small Particles. Wiley, 1983.
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Why the sky is blue -
Close-up of an iris -
Tyndall Effect -
The Tyndall Effect in Fog -
Koloidní povaha želatiny -
Interior of A. A. Skochinsky Mining Institute -
Lunar Laser at McDonald Observatory -
Internal Pantheon Light -
Water and Flour Suspension Liquid
.jpg)
