They will move apart until there is an infinite distance between them.
compression.
The particles that spread farther apart after the compression of a wave passing through air are called rarefactions. These regions of lower particle density are a result of the alternating compression and expansion of air particles as the wave travels through the medium.
When air particles are pushed together, they become more tightly packed and the air pressure increases. This can lead to an increase in temperature due to the compression of the particles.
When one part of a vibration causes air particles to spread out, it forms a rarefaction in the air. This is a region where the air particles are more spread out compared to the surrounding areas of compression. Together, these rarefactions and compressions create sound waves that propagate through the air.
Compression waves that can be heard are known as sound waves. These waves travel through a medium, such as air, and cause particles to vibrate, producing audible sound. Sound waves have different frequencies that determine pitch and amplitudes that determine volume.
compression.
The particles that spread farther apart after the compression of a wave passing through air are called rarefactions. These regions of lower particle density are a result of the alternating compression and expansion of air particles as the wave travels through the medium.
When air particles are pushed together, they become more tightly packed and the air pressure increases. This can lead to an increase in temperature due to the compression of the particles.
When one part of a vibration causes air particles to spread out, it forms a rarefaction in the air. This is a region where the air particles are more spread out compared to the surrounding areas of compression. Together, these rarefactions and compressions create sound waves that propagate through the air.
Compression happens during the part of the sound wave where the air particles are pushed closer together, resulting in an increase in air pressure. This creates a region of higher pressure within the sound wave, causing the compression of the air particles.
In a sound wave, compression areas are where the air particles are closely packed together, resulting in high pressure. Rarefaction areas are where the air particles are spread out, resulting in low pressure. These alternating areas of compression and rarefaction create the vibrations that we perceive as sound.
Compression waves that can be heard are known as sound waves. These waves travel through a medium, such as air, and cause particles to vibrate, producing audible sound. Sound waves have different frequencies that determine pitch and amplitudes that determine volume.
When a group of particles is squeezed in a wave, it refers to an increase in the density of the particles within that wave. This can happen, for example, in a compression wave where the particles are pushed closer together, resulting in an increase in pressure. This compression can be observed in various phenomena like sound waves or seismic waves.
The air particles are closest together at the compression regions of a sound wave. This is where the air pressure is at its highest, causing the particles to be more tightly packed.
When the drumhead moves downward, it compresses the air particles above it, increasing their pressure and density. This compression creates a wave of compressed air particles that propagates outward in all directions as a sound wave.
Rarefaction
In terms of particles, "compression" means that particles move closer together.