Difference between revisions of "Dissipation"
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==Origin== | ==Origin== | ||
[[Latin]] ''dissipātiōn''-''em'' , n. of [[action]] from ''dissipāre'' | [[Latin]] ''dissipātiōn''-''em'' , n. of [[action]] from ''dissipāre'' | ||
| − | *[ | + | *[https://en.wikipedia.org/wiki/15th_century 15th Century] |
==Definitions== | ==Definitions== | ||
*1: the [[action]] or [[process]] of dissipating : the state of being dissipated: a : [[dispersion]], [[diffusion]] | *1: the [[action]] or [[process]] of dissipating : the state of being dissipated: a : [[dispersion]], [[diffusion]] | ||
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*2: an [[act]] of self-indulgence; especially : one that is not harmful : amusement | *2: an [[act]] of self-indulgence; especially : one that is not harmful : amusement | ||
==Description== | ==Description== | ||
| − | In [[physics]], '''dissipation''' embodies the [[concept]] of a [ | + | In [[physics]], '''dissipation''' embodies the [[concept]] of a [https://en.wikipedia.org/wiki/Dynamical_system dynamical system] where important [[mechanical]] [[models]], such as [[waves]] or [https://en.wikipedia.org/wiki/Oscillation oscillations], lose [[energy]] over time, typically from [[friction]] or [[turbulence]]. The lost energy converts into [[heat]], which raises the [[temperature]] of the system. Such systems are called [https://en.wikipedia.org/wiki/Dissipative_system dissipative systems]. |
| − | For example, a [[wave]] that loses [ | + | For example, a [[wave]] that loses [https://en.wikipedia.org/wiki/Amplitude amplitude] is said to dissipate. The [[precise]] [[nature]] of the [[effects]] depends on the [[nature]] of the [[wave]]: an [https://en.wikipedia.org/wiki/Atmospheric_wave atmospheric wave], for instance, may dissipate close to the [[surface]] due to [[friction]] with the [[land]] mass, and at higher levels due to [https://en.wikipedia.org/wiki/Radiative_cooling radiative cooling]. |
| − | Dissipating forces are those that can not be described by [ | + | Dissipating forces are those that can not be described by [https://en.wikipedia.org/wiki/Hamiltonian_mechanics Hamiltonian] formalism. Loosely speaking, this includes [[friction]], and all similar [[forces]] that result in decoherency of [[energy]]—that is, conversion of coherent or directed energy [[flow]] into an indirected or more [https://en.wikipedia.org/wiki/Isotropic isotropic] [[distribution]] of [[energy]]. |
| − | In [ | + | In [https://en.wikipedia.org/wiki/Computational_physics computational physics], numerical dissipation (also known as "numerical diffusion") refers to certain side-effects that may occur as a result of a numerical solution to a differential equation. When the pure [https://en.wikipedia.org/wiki/Advection advection] equation, which is free of dissipation, is solved by a numerical approximation method, the energy of the initial wave may be reduced in a way [[analogous]] to a diffusional [[process]]. Such a method is said to contain 'dissipation'. In some cases, "artificial dissipation" is intentionally added to improve the [https://en.wikipedia.org/wiki/Numerical_stability numerical stability] characteristics of the solution. |
| − | A [[formal]], mathematical [[definition]] of dissipation, as commonly used in the mathematical study of [ | + | A [[formal]], mathematical [[definition]] of dissipation, as commonly used in the mathematical study of [https://en.wikipedia.org/wiki/Measure-preserving_dynamical_system measure-preserving dynamical systems], is given in the article [https://en.wikipedia.org/wiki/Wandering_set wandering set]. |
[[Category: Physics]] | [[Category: Physics]] | ||
Latest revision as of 23:56, 12 December 2020
Origin
Latin dissipātiōn-em , n. of action from dissipāre
Definitions
- 1: the action or process of dissipating : the state of being dissipated: a : dispersion, diffusion
- b archaic : dissolution, disintegration
- c : wasteful expenditure
- d : intemperate living; especially : excessive drinking
- 2: an act of self-indulgence; especially : one that is not harmful : amusement
Description
In physics, dissipation embodies the concept of a dynamical system where important mechanical models, such as waves or oscillations, lose energy over time, typically from friction or turbulence. The lost energy converts into heat, which raises the temperature of the system. Such systems are called dissipative systems.
For example, a wave that loses amplitude is said to dissipate. The precise nature of the effects depends on the nature of the wave: an atmospheric wave, for instance, may dissipate close to the surface due to friction with the land mass, and at higher levels due to radiative cooling.
Dissipating forces are those that can not be described by Hamiltonian formalism. Loosely speaking, this includes friction, and all similar forces that result in decoherency of energy—that is, conversion of coherent or directed energy flow into an indirected or more isotropic distribution of energy.
In computational physics, numerical dissipation (also known as "numerical diffusion") refers to certain side-effects that may occur as a result of a numerical solution to a differential equation. When the pure advection equation, which is free of dissipation, is solved by a numerical approximation method, the energy of the initial wave may be reduced in a way analogous to a diffusional process. Such a method is said to contain 'dissipation'. In some cases, "artificial dissipation" is intentionally added to improve the numerical stability characteristics of the solution.
A formal, mathematical definition of dissipation, as commonly used in the mathematical study of measure-preserving dynamical systems, is given in the article wandering set.
