0
What else can I help you with?
Does a sugar solution show the Tyndall effect?
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.
Who discovered Tyndall effect?
The Tyndall effect was discovered by the 19th-century physicist John Tyndall. He observed that when light passes through a colloidal solution, the particles in the solution scatter the light, making the beam visible. This effect is used to detect the presence of colloidal particles in a solution.
Does salt solution show slow tyndall effect?
No, salt solution does not typically show the Tyndall effect because the particles in a salt solution are dissolved at the molecular level and are too small to scatter light significantly. The Tyndall effect is typically observed with colloidal solutions where the particles are larger and can scatter light.
How is the Tyndall effect dependent upon particle size?
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.
What is the tyndell effect on salt solution?
The Tyndall effect is the scattering of light by particles in a colloid or suspension, making the light beam visible. In a salt solution, if the particles are small enough and evenly dispersed, they may not be large enough to scatter light significantly and produce a visible Tyndall effect. However, if there are larger particles present or the solution is more concentrated, the Tyndall effect may be observed.
Does a sugar solution show the Tyndall effect?
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.
Why does solution of Sodium Chloride not show Tyndall effect?
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.
How can the Tyndall effect to be used to distinguish between a colloid and a solution?
The Tyndall effect is specific for colloids, not for solutions.
Who discovered Tyndall effect?
The Tyndall effect was discovered by the 19th-century physicist John Tyndall. He observed that when light passes through a colloidal solution, the particles in the solution scatter the light, making the beam visible. This effect is used to detect the presence of colloidal particles in a solution.
Does a emulsion show the Tyndall effect?
yes.because when we are vigorous shaking the solution of two dissimilar liquids it it ii mix for 1 or 2 seconds .let it be the solution for 1 or 2 minutes it ll show the Tyndall effect ...so we can observe Tyndall effect in an emulsion solution .
A solution shows a Tyndall effect or soap shows Tyndall effect?
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.
Does salt solution show slow tyndall effect?
No, salt solution does not typically show the Tyndall effect because the particles in a salt solution are dissolved at the molecular level and are too small to scatter light significantly. The Tyndall effect is typically observed with colloidal solutions where the particles are larger and can scatter light.
How is the Tyndall effect dependent upon particle size?
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.
How can the Tyndall effect be used to distinguish between a colloid and a solution?
The Tyndall effect can be used to distinguish between a colloid and a solution by shining a light through the substance. In a colloid, the light will scatter due to the larger particles present, making the beam visible. In a solution, the light will pass straight through without scattering, making the beam less visible.
What is the tyndell effect on salt solution?
The Tyndall effect is the scattering of light by particles in a colloid or suspension, making the light beam visible. In a salt solution, if the particles are small enough and evenly dispersed, they may not be large enough to scatter light significantly and produce a visible Tyndall effect. However, if there are larger particles present or the solution is more concentrated, the Tyndall effect may be observed.
Is tyndall effect observed in true solution?
No, the Tyndall effect is not observed in true solutions. True solutions contain solute particles that are smaller than the wavelength of visible light, so they do not scatter light and appear transparent. The Tyndall effect is only observed in colloids or suspensions where the particles are larger and can scatter light, making the solution appear cloudy or opaque.
What is the tyndall effect used to distinguish between?
The Tyndall effect is used to distinguish between a solution and a colloid. In a solution, light passes through without scattering, while in a colloid, the dispersed particles cause light to scatter, making the beam visible.
