The speed of a longitudinal wave is determined by the properties of the medium through which it travels. Different mediums have different densities and elasticities, which affect how fast the wave can travel through them. In general, the speed of a longitudinal wave increases with the stiffness and density of the medium.
A disturbance that travels through a medium as a longitudinal wave is known as a sound wave. In a longitudinal wave, the particles of the medium oscillate parallel to the direction of wave propagation. Sound waves are an example of longitudinal waves as they require a medium, such as air or water, to travel through.
Longitudinal wave energy travels by the particles of the medium moving parallel to the direction of the wave. This causes compressions and rarefactions in the medium as the wave passes through. The energy is transferred through the collisions and interactions of the particles along the path of the wave.
It would be a longitudinal wave. If you were to conduct an experiment to see which wave travels in the same direction as the disturbance, you would take a slinky and push it. And if you watch the wave, you'll see that it travels through the slinky outward, and travels back to the disturbance (your hand). This wave is a longitudinal wave.
In longitudinal waves, energy is transferred in the form of mechanical energy. This energy is manifested through the compression and rarefaction of the medium that the wave travels through. Longitudinal waves are typically associated with sound waves, where energy is propagated through the compression and expansion of air molecules.
A longitudinal wave moves through a medium by causing particles in the medium to vibrate back and forth in the same direction as the wave's propagation. This creates areas of compression and rarefaction as the wave travels through the medium.
That is a longitudinal wave.
Light does that.
Longitudinal wave
A disturbance that travels through a medium as a longitudinal wave is known as a sound wave. In a longitudinal wave, the particles of the medium oscillate parallel to the direction of wave propagation. Sound waves are an example of longitudinal waves as they require a medium, such as air or water, to travel through.
The disturbance that travels through a medium as a compressional wave is called a longitudinal wave. In this type of wave, the particles of the medium move parallel to the direction of the wave's energy propagation. Sound waves are a common example of longitudinal waves.
Longitudinal wave energy travels by the particles of the medium moving parallel to the direction of the wave. This causes compressions and rarefactions in the medium as the wave passes through. The energy is transferred through the collisions and interactions of the particles along the path of the wave.
It would be a longitudinal wave. If you were to conduct an experiment to see which wave travels in the same direction as the disturbance, you would take a slinky and push it. And if you watch the wave, you'll see that it travels through the slinky outward, and travels back to the disturbance (your hand). This wave is a longitudinal wave.
In longitudinal waves, energy is transferred in the form of mechanical energy. This energy is manifested through the compression and rarefaction of the medium that the wave travels through. Longitudinal waves are typically associated with sound waves, where energy is propagated through the compression and expansion of air molecules.
A longitudinal wave moves through a medium by causing particles in the medium to vibrate back and forth in the same direction as the wave's propagation. This creates areas of compression and rarefaction as the wave travels through the medium.
Always longitudinal.
a medium. but longitudinal waves do not have to travel through a medium. This is why transverse waves cannot vibrate through space.a medium. but longitudinal waves do not have to travel through a medium. This is why transverse waves cannot vibrate through space.
Sound is a longitudinal wave. Hence, it travels through the air through compressions and rarefractions of molecules. This is also why it cannot travel through a vacuum.