Vibrational spectrum: Difference between revisions

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{{Image|Circular Vibration.png|right|250px|Snapshot of one possible vibration of a circular membrane at successive instants of time.}}
The '''vibrational spectrum''' of a mechanical system such as a [[molecule]], [[crystal]], or a [[musical instrument]] is the set of frequencies exhibited by regular, periodic motions of the parts of the system relative to one another that persist once excited without requiring an external driving agency. That is, the vibrational spectrum refers to free, not forced, vibration of the system.
The '''vibrational spectrum''' of a mechanical system such as a [[molecule]], [[crystal]], or a [[musical instrument]] is the set of frequencies exhibited by regular, periodic motions of the parts of the system relative to one another that persist once excited without requiring an external driving agency. That is, the vibrational spectrum refers to free, not forced, vibration of the system.



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(PD) Image: John R. Brews
Snapshot of one possible vibration of a circular membrane at successive instants of time.

The vibrational spectrum of a mechanical system such as a molecule, crystal, or a musical instrument is the set of frequencies exhibited by regular, periodic motions of the parts of the system relative to one another that persist once excited without requiring an external driving agency. That is, the vibrational spectrum refers to free, not forced, vibration of the system.

Mechanical systems that vibrate exhibit a restoring force when displaced from their equilibrium configuration, and an inertia that causes the restoring motion to overshoot the equilibrium position, resulting in a periodic motion that normally damps out over time.

From an energy viewpoint, such systems exhibit the capacity to store potential energy in a spring-like mechanism, to convert it to kinetic energy by virtue of their motion, and to gradually return to equilibrium through some damping mechanism that dissipates the energy of vibration.[1]

References

  1. Thomas D. Rossing, Neville Horner Fletcher (2004). Principles of Vibration and Sound, 2nd. Springer, pp. 3 ff. ISBN 0387405569.