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The core, with its vibration causes an increase in waves. The shaking elevates the P wavers, also known as the sound waves. Further from the epicenter, the p waves are slower.
Yes, the speed of sound in air does increase with an increase in temperature. This is because higher temperatures lead to increased molecular motion, which in turn allows sound waves to travel faster through the medium.
No, it causes a huge decrease in speed.
The speed of sound waves will increase when they travel from air to water. This is because sound travels faster in water due to water molecules being closer together, allowing the vibrations to propagate more quickly.
The speed of sound is directly proportional to the square root of the temperature of the medium. This relationship exists because higher temperatures lead to faster molecular motion, resulting in an increase in the speed at which sound waves can travel through the medium.
The speed of sound depends on the medium the waves pass through, and is a fundamental property of the material. It itself cannot increase wave length as it is merely a property and not an active force that can modify anything.
The waves compress which causes a lower tonal quality.
High pressure can increase the speed of sound transmission and alter the frequency of sound waves. It can also affect the way sound is perceived by the human ear, potentially causing discomfort or distortion in hearing.
Increase the volume.
Yes, as air temperature increase so does the speed of sound. This is due to the individual air particles having extra kinetic energy at higher temperatures, allowing vibrations of sound waves to pass easily.
The pitch of a sound, which is determined by its frequency, does not affect its speed. The speed of sound in air at room temperature is roughly 343 meters per second. This speed is independent of the pitch of the sound wave.
Yes, increasing the tension in a spring will increase the speed at which waves propagate through it. This is because the speed of the wave is proportional to the square root of the tension in the spring.