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16.6: Speed of a Transverse Wave

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Speed of a Transverse Wave

16.6: Speed of a Transverse Wave

The speed of a wave depends on the characteristics of the medium. For example, in the case of a guitar, the strings vibrate to produce the sound. The speed of the waves on the strings and the wavelength determine the frequency of the sound produced. The strings on a guitar have different thicknesses but may be made of similar material. They have different linear densities, and the linear density is defined as the mass per length.

One of the key properties of any wave is the wave speed. Light waves have a much greater propagation speed than sound waves in the air. For that reason, a flash is seen from a lightning bolt before the clap of thunder is heard. It is important to understand the speed of transverse waves on a string because this speed is essential for analyzing stringed musical instruments. Furthermore, the speeds of many kinds of mechanical waves have the same primary mathematical expression as the speed of waves on a string. The physical quantities that determine the speed of transverse waves on a string are the tension in the string and its mass per unit length (also called the linear mass density). Increasing the tension increases the restoring forces that tend to straighten the string when disturbed, thus increasing the wave speed. Increasing the mass makes the motion more sluggish and decreases the speed.

Suggested Reading


Keywords: Transverse Wave Wave Speed Linear Density Tension Stringed Musical Instruments Mechanical Waves Wavelength Frequency Mass Per Length

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