Don't think so - all my references show it's to do with air pressure in constricted flow.
Check you question.
You are correct. The Venturi effect has nothing to do with light. It is the ability to create positive and negative pressures with various tubes. Siphons work on a venturi principle for example.
The Tyndall effect is the scattering of light by the particles in a colloid or fine suspension. This effect causes the beam of light to become visible as it passes through the colloidal mixture or suspension due to the reflection and dispersion of light by the particles.
The Tyndall effect is based on the scattering of light by particles in a colloidal solution. The larger the particles in the solution, the more pronounced the scattering of light will be, leading to a more noticeable Tyndall effect. Smaller particles have less pronounced scattering, making the effect less visible.
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.
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.
If the mixture is completely homogeneous, then the mixture is true solution as in the solution the solute particles are completely dissolved and have uniform composition. These are transparent.
This is because there are solid particles suspended in the mixture although it is more stable than a suspension.
The Tyndall effect is the scattering of light by the particles in a colloid or fine suspension. This effect causes the beam of light to become visible as it passes through the colloidal mixture or suspension due to the reflection and dispersion of light by the particles.
Yes, it does because tyndall effect is caused by scattering of light by small particles in colloidal solutions in transparent medium. (colloid means the mixture of particles less than size of particles in suspension)
The Tyndall effect is based on the scattering of light by particles in a colloidal solution. The larger the particles in the solution, the more pronounced the scattering of light will be, leading to a more noticeable Tyndall effect. Smaller particles have less pronounced scattering, making the effect less visible.
tyndall effect
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.
tyndall effect
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.
Tyndall effect
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.
This scattering of light by small particles is known as the Tyndall effect. It occurs when light strikes particles in a medium, causing the light to scatter in different directions, making the beam visible. This effect is commonly observed in colloids, dust particles in the air, or fog.
the scattering of light by colloids is known as tyndall effect. it is named after the scientist who discovered it.