When you shine light through a mirror, the light will reflect off the mirror's surface and bounce back. Some light may also pass through the mirror, depending on its transparency. Overall, the mirror will predominantly reflect the light due to its smooth and reflective surface.
When you shine a beam of light on a mirror, the light is reflected off the mirror's surface. The angle of incidence (the angle at which the light beam hits the mirror) is equal to the angle of reflection (the angle at which the light beam bounces off the mirror). This is known as the law of reflection.
When you shine a light into a mirror, the light reflects off the mirror's surface and bounces back in the opposite direction. This is called specular reflection. The angle at which the light hits the mirror will be equal to the angle at which it bounces off.
If you shine a mirror at another mirror, the light will bounce off the first mirror, reflect off the second mirror, and then bounce back to the first mirror. This will create an infinite loop of reflections as the light continues to bounce back and forth between the mirrors.
When you shine a flashlight at a mirror, the ray of light that shines back at you is the ray of reflection, not incidence. The ray of incidence is the incoming ray of light that strikes the mirror. The ray of reflection is the outgoing ray that bounces off the mirror at an equal but opposite angle to the incident ray.
When you shine a laser at a mirror, the light beam gets reflected off the mirror's surface. The angle of reflection is equal to the angle of incidence, following the law of reflection. The mirror will redirect the laser beam in a predictable direction.
it reflects
When you shine a beam of light on a mirror, the light is reflected off the mirror's surface. The angle of incidence (the angle at which the light beam hits the mirror) is equal to the angle of reflection (the angle at which the light beam bounces off the mirror). This is known as the law of reflection.
When you shine a light into a mirror, the light reflects off the mirror's surface and bounces back in the opposite direction. This is called specular reflection. The angle at which the light hits the mirror will be equal to the angle at which it bounces off.
If you shine a mirror at another mirror, the light will bounce off the first mirror, reflect off the second mirror, and then bounce back to the first mirror. This will create an infinite loop of reflections as the light continues to bounce back and forth between the mirrors.
When you shine a flashlight at a mirror, the ray of light that shines back at you is the ray of reflection, not incidence. The ray of incidence is the incoming ray of light that strikes the mirror. The ray of reflection is the outgoing ray that bounces off the mirror at an equal but opposite angle to the incident ray.
When you shine a laser at a mirror, the light beam gets reflected off the mirror's surface. The angle of reflection is equal to the angle of incidence, following the law of reflection. The mirror will redirect the laser beam in a predictable direction.
The reflection of light from surface of a mirror makes it shining. When the light passes through glass, it does not shine. When one side of this glass is covered by a substance that does not allow light to pass through, the light gets reflected and it shines.
Colours shine out!
It goes out the other side.
the light doesnt go through the fog
A compound microscope can either have a light bulb or a mirror for illumination. If your microscope has a mirror, then you need sunlight or some other light source to point at the mirror to view your slide.The mirror is used to focus light up through the hole in the microscope's stage, or slide platform. The slides will contain a thin slice of material through which the light can shine, to reveal the internal structure of the sample.
Shining a flashlight on a mirror in a dark place will reflect the light back towards the source, creating a brighter and more focused beam of light. The mirror will redirect the light waves without scattering them, maximizing the illumination in the direction of the flashlight.