Light waves are produced by the vibration of electrically charged particles, typically electrons, within atoms or molecules. This vibration generates electromagnetic radiation in the form of light waves. Examples of natural sources of light waves include the sun, stars, and fire, while man-made sources include light bulbs, lasers, and LEDs.
Sound waves are created by vibrations in a medium (such as air, water, or solids), which produce changes in pressure that propagate as waves. Light waves are created by the oscillation of electric and magnetic fields, typically resulting from the movement of charged particles or transitions in atomic structures.
yes, light travels through vibrations. light vibrations are in the form of pure energy. it travels in the form of pure electro-magnetic radiation. therefore light can travel in both withought vibration and with vibration.
Light travels in waves, and sound travels in waves. However, sound waves and light waves are very different, and it is important not to confuse the two. Light travels in electromagnetic waves, and sound does not. Sound waves are caused by vibration.
Interference is a phenomenon demonstrated by light but not by sound waves. Interference occurs when two or more waves overlap in space and combine to produce a resultant wave. Light waves can exhibit interference patterns such as in Young's double-slit experiment, while sound waves do not exhibit similar interference effects.
Light waves are electromagnetic waves that can travel through a vacuum, while seismic waves are mechanical waves that require a medium, such as rocks or soil, to propagate. Light waves travel at the speed of light (about 300,000 km/s), while seismic waves travel at much slower speeds (a few km/s to several km/s). Light waves exhibit characteristics such as reflection and refraction, while seismic waves can produce earthquakes and reveal information about the Earth's interior.
yes
Light has the property of being an electromagnetic wave.
Sound waves are created by vibrations in a medium (such as air, water, or solids), which produce changes in pressure that propagate as waves. Light waves are created by the oscillation of electric and magnetic fields, typically resulting from the movement of charged particles or transitions in atomic structures.
Heavy stones produce more waves than light stones when thrown into water because they displace more water due to their weight. The displacement creates more ripples and waves on the surface of the water.
yes, light travels through vibrations. light vibrations are in the form of pure energy. it travels in the form of pure electro-magnetic radiation. therefore light can travel in both withought vibration and with vibration.
Light travels in waves, and sound travels in waves. However, sound waves and light waves are very different, and it is important not to confuse the two. Light travels in electromagnetic waves, and sound does not. Sound waves are caused by vibration.
ultraviolet waves
Interference is a phenomenon demonstrated by light but not by sound waves. Interference occurs when two or more waves overlap in space and combine to produce a resultant wave. Light waves can exhibit interference patterns such as in Young's double-slit experiment, while sound waves do not exhibit similar interference effects.
Light waves are electromagnetic waves that can travel through a vacuum, while seismic waves are mechanical waves that require a medium, such as rocks or soil, to propagate. Light waves travel at the speed of light (about 300,000 km/s), while seismic waves travel at much slower speeds (a few km/s to several km/s). Light waves exhibit characteristics such as reflection and refraction, while seismic waves can produce earthquakes and reveal information about the Earth's interior.
In a flashlight, electromagnetic waves are used to generate light. When electricity flows through the circuit, it excites the atoms in the light bulb's filament, causing them to emit light in the form of electromagnetic waves. The waves in the visible spectrum produce the light that we see when we turn on a flashlight.
waves produce in string fixed at one end sunlight as clear from polarization
For a point in space (or from a distant light object), spherical waves are emitted. From a point source on the surface of a liquid, circular waves will come out. In both cases the source will be the focus of the emitted waves.