because the particles vibrate back and forth due to which compression and rarefactions are made
Transverse waves have crests and troughs. Longitudinal waves have compressions and rarefactions.
Neon cat
The wavelength of a compressional wave is the distance between two adjacent compressions or rarefactions.
Compressions and rarefactions are kinds of pressure variations that occur in a wave. In a compression, the particles are close together, creating a higher pressure region while in a rarefaction, the particles are spread apart, creating a lower pressure region.
As sound is an example of a longitudinal wave, sound has a series of compressions and rarefactions.To explain a bit more, compressions are the squeezes of the wave while rarefactions are the stretches of the wave.
Compressions are the parts where the coils are close together
No, compressions and rarefactions are characteristics of longitudinal waves, not transverse waves. In transverse waves, the particles of the medium move perpendicular to the direction of the wave propagation.
Sound waves have compressions and rarefactions. Compressions are areas where molecules are close together, creating high pressure, while rarefactions are areas where molecules are spread out, creating low pressure.
Compressions and rarefactions are regions of high and low pressure in a longitudinal wave, while crests and troughs are points of maximum positive and negative displacement in a transverse wave. Both terms describe different aspects of wave behavior: compressions and rarefactions in longitudinal waves, and crests and troughs in transverse waves.
With the help of compressions and rarefactions longitudinal waves get propagated.
Compressions and rarefactions of the media in which it is considered. In a vacuum, no media so no sound.
rarefactions, which are regions of high and low pressure respectively. As the wave travels through a medium, these compressions and rarefactions propagate in a wave pattern, carrying energy from one point to another.