A rarefaction., in contrast to a compression.
Answer 1: A compressional wave is a wave that is close together and transverse waves are waves that are going the way the wave travels. Answer 2: Basically, it's a sound wave. A compressional wave is a wave that travels back and forth, moving with compression. Scince it is a mechanical wave it must use a medium to travel though. A sound wave is a good example of a compressional wave. A compressional wave is a wave that travels back and forth, moving with compression. Scince it is a mechanical wave it must use a medium to travel though. A sound wave is a good example of a compressional wave. ================================================================ its since, stupid.
The compression region of a compressional wave, also known as a rarefaction wave, is where the medium particles are crowded and dense. This occurs when the particles are pushed together, resulting in a region of increased pressure and density compared to the surrounding areas.
I believe you are referring to rarefaction. The "trough" of a compression / rarefaction wave is called rarefaction.
The more crowded area or more dense area of a compressional wave is called the compression or the crest of the wave. This is where the particles of the medium are closer together and the pressure is higher.
When the trough of a wave and the crest of a different wave meet, the waves cancel completely. This is called destructive interference.
In a compressional wave, the particles are spaced farthest apart at the points of maximum rarefaction where the wave is at its trough. This is when the pressure is at its lowest and the particles are more spread out.
The particles in a compressional wave are spaced farthest apart at the rarefaction region, which corresponds to the trough of the wave where the pressure and density are lower than normal.
The spread-apart portion of a compressional wave is called a rarefaction. In a compressional wave, particles are pushed together (compression) and then spread apart (rarefaction) as the wave passes through a medium.
The part of a compressional wave with the greatest density is the compression region, where particles are closest together due to the wave's compressional nature. This region represents the highest density of particles in the wave's pattern.
The area on a compressional wave where particles are spread out is called a rarefaction. In a rarefaction, the particles are further apart compared to the surrounding areas where they are closer together. This alternating pattern of compressions and rarefactions is characteristic of a longitudinal wave such as a sound wave.
When the waves are spread apart in a compressional wave, it is referred to as rarefaction. This is when the particles in the medium are further apart from each other compared to the compression phase, resulting in a decrease in density.
Yes, a compressional wave does contain rarefactions. In a compressional wave, particles are squeezed together (compression) and subsequently spread apart (rarefaction), resulting in alternating regions of high and low pressure as the wave travels through a medium.
A sound wave is a compressional wave, which means the particles in the medium vibrate parallel to the direction of the wave propagation. This compression and rarefaction of particles create the variations in pressure that we perceive as sound.
This type of wave is a compressional wave, also known as a longitudinal wave. In this wave, the particles move parallel to the direction of the wave propagation, causing regions of compression and rarefaction as it moves through a medium. Examples of compressional waves include sound waves.
The two types of regions in a compressional wave are compression regions, where particles are close together and experience high pressure, and rarefaction regions, where particles are spread apart and experience low pressure.
Rarefaction is the part of a longitudinal wave where the particles are spread apart.
sound behaves as a compressional wave, look at a photo of it. I'll try to draw it, but it 's gonna suck direction of propagation -----> * * * * * * * ** * * * * * * * ** **** * * * * * * * * *** * *