Dissipation rate: Difference between revisions

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<div class="definition"><div class="short_definition">The rate of conversion of [[turbulence]] into [[heat]] by [[molecular viscosity]].</div><br/> <div class="paragraph">Defined as  <div class="display-formula"><blockquote>[[File:ams2001glos-De30.gif|link=|center|ams2001glos-De30]]</blockquote></div> where (''u''&prime;, ''v''&prime;, ''w''&prime;) are the turbulent [[perturbation]] velocities (instantaneous deviations from respective  mean velocities) in the (''x'', ''y'', ''z'') directions, &#x003bd; is the [[kinematic viscosity]] of air, and the  overbar indicates an average. This conversion always acts to reduce [[turbulence kinetic energy]]  and means that turbulence is not a conserved [[variable]]. It also causes turbulence to decay to zero  unless there is continual regeneration of turbulence by other mechanisms. Turbulence [[dissipation]]  is greatest for the smallest-size [[eddies]] (on the order of millimeters in diameter), but turbulence is  usually produced as larger eddies roughly the size of the [[atmospheric boundary layer]] (on the  order of hundreds of meters). The [[transfer]] of turbulence kinetic energy from the largest to the  smallest eddies is called the inertial cascade, and the rate of this [[energy transfer]] is directly  proportional to the dissipation rate for turbulence that is stationary ([[steady state]]). The medium-  size eddies where turbulence is neither created nor destroyed is called the [[inertial subrange]].  [[Similarity theory]] ([[dimensional analysis]]) allows calculation of the dissipation rate from measurements  of turbulence spectral intensity ''S''(&#x003ba;) at [[wavelength]] &#x003ba;, via &#x003b5; = 0.49''S''<sup>3/2</sup>&#x003ba;<sup>5/2</sup>. Typical orders  of magnitude for &#x003b5; are 10<sup>&minus;2</sup> to 10<sup>&minus;3</sup> m<sup>2</sup> s<sup>&minus;3</sup> during daytime [[convection]], and 10<sup>&minus;6</sup> to 10<sup>&minus;4</sup> m<sup>2</sup> s<sup>&minus;3</sup>  at night.</div><br/> </div><div class="reference">Stull, R. B. 1988. An Introduction to Boundary Layer Meteorology. 347&ndash;404. </div><br/>  
<div class="definition"><div class="short_definition">The rate of conversion of [[turbulence]] into [[heat]] by [[molecular viscosity]].</div><br/> <div class="paragraph">Defined as  <div class="display-formula"><blockquote>[[File:ams2001glos-De30.gif|link=|center|ams2001glos-De30]]</blockquote></div> where (''u''&prime;, ''v''&prime;, ''w''&prime;) are the turbulent [[perturbation]] velocities (instantaneous deviations from respective  mean velocities) in the (''x'', ''y'', ''z'') directions, &#x003bd; is the [[kinematic viscosity]] of air, and the  overbar indicates an average. This conversion always acts to reduce [[turbulence kinetic energy]]  and means that turbulence is not a conserved [[variable]]. It also causes turbulence to decay to zero  unless there is continual regeneration of turbulence by other mechanisms. Turbulence [[dissipation]]  is greatest for the smallest-size [[eddies]] (on the order of millimeters in diameter), but turbulence is  usually produced as larger eddies roughly the size of the [[atmospheric boundary layer]] (on the  order of hundreds of meters). The [[transfer]] of turbulence kinetic energy from the largest to the  smallest eddies is called the inertial cascade, and the rate of this [[energy transfer]] is directly  proportional to the dissipation rate for turbulence that is stationary ([[steady state]]). The medium-  size eddies where turbulence is neither created nor destroyed is called the [[inertial subrange]].  [[Similarity theory]] ([[dimensional analysis]]) allows calculation of the dissipation rate from measurements  of turbulence spectral intensity ''S''(&#x003ba;) at [[wavelength]] &#x003ba;, via &#x003b5; = 0.49''S''<sup>3/2</sup>&#x003ba;<sup>5/2</sup>. Typical orders  of magnitude for &#x003b5; are 10<sup>-2</sup> to 10<sup>-3</sup> m<sup>2</sup> s<sup>-3</sup> during daytime [[convection]], and 10<sup>-6</sup> to 10<sup>-4</sup> m<sup>2</sup> s<sup>-3</sup>  at night.</div><br/> </div><div class="reference">Stull, R. B. 1988. An Introduction to Boundary Layer Meteorology. 347&ndash;404. </div><br/>  
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Revision as of 14:04, 20 February 2012



dissipation rate

The rate of conversion of turbulence into heat by molecular viscosity.

Defined as
ams2001glos-De30
where (u′, v′, w′) are the turbulent perturbation velocities (instantaneous deviations from respective mean velocities) in the (x, y, z) directions, ν is the kinematic viscosity of air, and the overbar indicates an average. This conversion always acts to reduce turbulence kinetic energy and means that turbulence is not a conserved variable. It also causes turbulence to decay to zero unless there is continual regeneration of turbulence by other mechanisms. Turbulence dissipation is greatest for the smallest-size eddies (on the order of millimeters in diameter), but turbulence is usually produced as larger eddies roughly the size of the atmospheric boundary layer (on the order of hundreds of meters). The transfer of turbulence kinetic energy from the largest to the smallest eddies is called the inertial cascade, and the rate of this energy transfer is directly proportional to the dissipation rate for turbulence that is stationary (steady state). The medium- size eddies where turbulence is neither created nor destroyed is called the inertial subrange. Similarity theory (dimensional analysis) allows calculation of the dissipation rate from measurements of turbulence spectral intensity S(κ) at wavelength κ, via ε = 0.49S3/2κ5/2. Typical orders of magnitude for ε are 10-2 to 10-3 m2 s-3 during daytime convection, and 10-6 to 10-4 m2 s-3 at night.

Stull, R. B. 1988. An Introduction to Boundary Layer Meteorology. 347–404.


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