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Foam scatters light because of the irregular surfaces and structures of its bubbles, which cause light to bounce in different directions. When light encounters these surfaces, it is reflected and refracted in various directions, resulting in the appearance of scattered light. The small size of the bubbles in foam also contributes to the scattering of light waves.

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What mixtures will not scatter light?

sollution


What of these mixtures would not scatter light?

A mixture that would not scatter light is a solution where the solute is completely dissolved at the molecular or ionic level, such as salt in water. In this case, the particles are too small to interfere with the passage of light, resulting in a clear solution. In contrast, mixtures with larger particles, like suspensions or colloids, would scatter light.


Phenomenon observed when beam of light passes through a colloid?

The Tyndall effect is observed when a beam of light passes through a colloid, causing the light to scatter and become visible. This phenomenon occurs due to the particles in the colloid being large enough to scatter light, unlike in a true solution where particles are too small to scatter light. The Tyndall effect is commonly used to determine if a mixture is a true solution or a colloid.


Why true solution do not scatter light?

True solutions do not scatter light because their solute particles are molecular or ionic in size, which is much smaller than the wavelength of visible light. As a result, the light waves pass through the solution without being deflected or scattered. This contrasts with colloidal solutions, where larger particles can scatter light, leading to phenomena like the Tyndall effect. In true solutions, the uniform distribution of solute at the molecular level allows for clear transmission of light.


What does it mean that colloids scatter light?

When colloids scatter light, it means that the particles in the colloid are large enough to disrupt the path of light passing through them. This scattering effect causes the light to be reflected in different directions, making the colloid appear cloudy or opaque.