They are reflected or absorbed.
nope.. they are Refracted
When light rays hit an opaque object, they are absorbed or reflected. The object appears opaque because it reflects most of the light that hits it and absorbs very little. This is why we cannot see through opaque objects.
They are reflected at the angle of incidence.
This phenomenon is called reflection. When light rays hit a surface and bounce off, they create an image of the object.
When parallel rays of light hit a smooth surface, they are reflected at the same angle they hit the surface. This is described by the law of reflection. The reflected rays remain parallel to each other.
When light rays hit the surface of a flat mirror, they are reflected back at the same angle as they approached the mirror. This is known as the law of reflection. The image seen in the mirror is a virtual image that appears to be the same distance behind the mirror as the object is in front of it.
When light rays hit the specimen in a microscope, they can be absorbed, transmitted through, or reflected by the specimen. The interaction between the light and the specimen allows for imaging and visualization of the specimen's details.
When light rays bounce off a surface and back to your eyes, the process is called reflection. This allows you to see the object the light rays bounced off of. The angle at which the light rays are reflected depends on the angle at which they hit the surface, following the law of reflection.
When parallel rays of light hit a rough or bumpy surface, they get scattered in different directions due to reflection. This phenomenon is known as diffuse reflection. The surface roughness causes the light to reflect unevenly, leading to the diffusion of light in various directions.
Shadows are formed when an object blocks the path of light rays, creating an area of darkness behind it. Two reasons shadows are formed are: (1) when light rays hit an opaque object and are unable to pass through it, and (2) when light rays are absorbed or reflected by an object, creating a shadow on the surface behind it.
Light rays reflect when they hit a concave mirror. The parallel rays of light converge at the focal point after reflection.
When a light ray hits the surface of a convex mirror, it reflects off the mirror divergently. This means that the reflected light rays appear to originate from a virtual focal point behind the mirror, creating an upright and smaller image of the object.
The electrons in the lead become excited and emit light of particular frequencies unique to lead.