The scattering of light by a colloid is called Tyndall effect. This effect occurs when light is scattered by particles within a colloid, making the beam of light visible due to the reflection and absorption of light by the colloidal particles.
No, Michael Faraday did not discover the Tyndall effect. The Tyndall effect refers to the scattering of light by colloidal particles in a transparent medium and was actually named after the Irish physicist John Tyndall, who first explained the phenomenon in the 19th century.
The Tyndall effect, or Tyndall scattering, was named after 19th century physicist John Tyndall. It has to do with light scattering through particles in a suspension.
No, a sugar solution does not typically show the Tyndall effect. The Tyndall effect is the scattering of light by colloidal particles, but sugar molecules are generally too small to scatter light effectively.
The Tyndall effect is the scattering of light by particles in a colloid or fine suspension, making the beam of light visible. In a sugar solution, which is a true solution (not a colloid), the particles are too small to scatter light significantly, so the Tyndall effect is not observed.
The scattering of light by a colloid is called Tyndall effect. This effect occurs when light is scattered by particles within a colloid, making the beam of light visible due to the reflection and absorption of light by the colloidal particles.
No, Michael Faraday did not discover the Tyndall effect. The Tyndall effect refers to the scattering of light by colloidal particles in a transparent medium and was actually named after the Irish physicist John Tyndall, who first explained the phenomenon in the 19th century.
the scattering of light by colloids is known as tyndall effect. it is named after the scientist who discovered it.
The Tyndall effect, or Tyndall scattering, was named after 19th century physicist John Tyndall. It has to do with light scattering through particles in a suspension.
The Tyndall effect is specific for colloids, not for solutions.
No, a sugar solution does not typically show the Tyndall effect. The Tyndall effect is the scattering of light by colloidal particles, but sugar molecules are generally too small to scatter light effectively.
The key word here is "solution". Solutions do not exhibit the Tyndall effect; if something does exhibit the Tyndall effect, that's a good indication that it is not a solution.
The Tyndall effect is the phenomenon where light is scattered by particles in a colloidal solution or suspension, making the beam visible. If a solution is showing the Tyndall effect, it indicates the presence of suspended particles that are large enough to scatter light. In the case of soap, the Tyndall effect may be observed when light is scattered by micelles or other structures in the soap that are similar in size to the wavelength of visible light.
The Tyndall effect is used commercially to determine the size and density of particles in aerosols.
No, rubber does not show the Tyndall effect. The Tyndall effect is the scattering of light by colloidal particles or particles suspended in a transparent medium, which causes the light to be visible as a beam. Rubber does not have the scattering properties required to exhibit this effect.
Yes, colloids can exhibit the Tyndall effect, which is the scattering of light by particles in a colloid suspension. This effect is used to differentiate between colloidal and true solutions.
The Tyndall effect is the scattering of light by particles in a colloid or fine suspension, making the beam of light visible. In a sugar solution, which is a true solution (not a colloid), the particles are too small to scatter light significantly, so the Tyndall effect is not observed.