Collisionality: Difference between revisions

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Consider a test particle with charge ''q'', mass ''m'', and velocity ''v'' colliding with bulk particles with charge ''q*'', mass ''m*'', and thermal velocity ''v*''. Then the collision frequency ''&nu; = 1/&tau;<sub>coll</sub>'' is given by
Consider a test particle with charge ''q'', mass ''m'', and velocity ''v'' colliding with bulk particles with charge ''q*'', mass ''m*'', and thermal velocity ''v*''. Then the collision frequency ''&nu; = 1/&tau;<sub>coll</sub>'' is given by
<ref>K. Miyamoto, ''Plasma Physics and Controlled Nuclear Fusion'', Springer-Verlag (2005) ISBN 3540242171</ref>
<ref>K. Miyamoto, ''Plasma Physics and Controlled Nuclear Fusion'', Springer-Verlag (2005) {{ISBN|3540242171}}</ref>


:<math>\nu = \left ( \frac{qq^*n^*}{\varepsilon_0 m}\right )^2 \frac{\ln \Lambda}{4\pi (m_r/m)v^3n^*}</math>
:<math>\nu = \left ( \frac{qq^*n^*}{\varepsilon_0 m}\right )^2 \frac{\ln \Lambda}{4\pi (m_r/m)v^3n^*}</math>


assuming ''v > v*'', where ''m<sub>r</sub> = mm*/(m+m*)'' is the reduced mass and ''n*'' the bulk particle density.
assuming ''v > v*'', where ''m<sub>r</sub> = mm*/(m+m*)'' is the reduced mass and ''n*'' the bulk particle density.
The factor ln &Lambda; appears due to the accumulation of many small-angle collisions within a Debye sphere.
The factor ln &Lambda; appears due to the accumulation of many small-angle collisions within a [[Debye length|Debye sphere]].


== Dimensionless collisionality ==
== Dimensionless collisionality ==
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<ref>[http://dx.doi.org/10.1088/0029-5515/39/12/301 ITER Physics Basis, Nucl. Fusion '''39''' (1999) 2137]</ref>
<ref>[http://dx.doi.org/10.1088/0029-5515/39/12/301 ITER Physics Basis, Nucl. Fusion '''39''' (1999) 2137]</ref>


:<math>\nu* = \frac{\rm connection~length}{\rm trapped~particle~mean~free~path}</math>
:<math>\nu^* = \frac{\rm connection~length}{\rm trapped~particle~mean~free~path}</math>
 
See [[Connection length]]. The mean free path is estimated by the thermal velocity divided by the collision frequency, ''v<sub>th</sub> / &nu;''.


== References ==
== References ==
<references />
<references />

Latest revision as of 11:36, 26 January 2023

In a plasma, the collision time τcoll is defined as the time in which the trajectory of a (charged) particle undergoes a change of direction of 90 degrees. Due to the long range of the Coulomb force, Coulomb interactions are typically small angle scattering events, so that this direction change typically requires a large number of interactions.

Consider a test particle with charge q, mass m, and velocity v colliding with bulk particles with charge q*, mass m*, and thermal velocity v*. Then the collision frequency ν = 1/τcoll is given by [1]

assuming v > v*, where mr = mm*/(m+m*) is the reduced mass and n* the bulk particle density. The factor ln Λ appears due to the accumulation of many small-angle collisions within a Debye sphere.

Dimensionless collisionality

The dimensionless collisionality ν* is defined as [2]

See Connection length. The mean free path is estimated by the thermal velocity divided by the collision frequency, vth / ν.

References

  1. K. Miyamoto, Plasma Physics and Controlled Nuclear Fusion, Springer-Verlag (2005) ISBN 3540242171
  2. ITER Physics Basis, Nucl. Fusion 39 (1999) 2137