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{{Distinguish|Plasma parameters}}
The ''plasma parameter'' is a dimensionless number, denoted by capital Lambda, Λ. One definition of this parameter is given by the average number of electrons in a [[plasma (physics)|plasma]] contained within a [[Debye sphere]] (a sphere of radius the [[Debye length]]). Note that the word parameter is usually used in plasma physics to refer to bulk plasma properties in general: see [[plasma parameters]]. In this context, the plasma parameter is defined as▼
<math display="block">\Lambda = 4\pi n_\text{e}\lambda_\text{D}^3</math>
where
This expression is typically valid for a plasma in which ion thermal velocities are much less than electron thermal velocities. A detailed discussion of the Coulomb logarithm is available in the ''NRL Plasma Formulary'', pages 34–35.
Often the factor of <math>4\pi/3</math> is dropped. When the Debye length is given by <math> \lambda_D = \sqrt{\frac{\epsilon_0 k T_e}{n_e q_e^2}}</math>, the plasma parameter is given by<ref>Miyamoto, K., Fundamentals of Plasma Physics and Controlled Fusion, (Iwanami, Tokyo, 1997)</ref>▼
Note that the word parameter is usually used in plasma physics to refer to bulk plasma properties in general: see [[plasma parameters]].
▲
<math display="block">N_\text{D} = \frac{4\pi}{3} n_\text{e}\lambda_\text{D}^3 = \frac{1}{3}\Lambda</math>
Since these two definitions differ only by a factor of three, they are frequently used interchangeably.
▲Often the factor of <math>\frac{4\pi
<math display="block">N_\text{D} = \frac{{\left(\varepsilon_0 k_\text{B} T_\text{e}\right)}^{3/2}}{q_\text{e}^3 {n_\text{e}}^{1/2}}
= \left(\frac{k_\text{B} T_e}{n_e^{1/3}}\right)^{3/2} \left(\frac{q_e^2}{\varepsilon_0}\right)^{-3/2}</math>
where
Confusingly, some authors define the plasma parameter as
== Coupling parameter ==
▲:<math> \epsilon_p = \Lambda^{-1}\ </math>.
A closely related parameter is the plasma coupling <math>\Gamma</math>, defined as a ratio of the Coulomb energy to the thermal one:
▲An alternative interpretation, and one more frequently encountered in scientific literature, defines Λ as the ratio of the maximum impact parameter to the classical distance of closest approach in [[Coulomb_collision |Coulomb scattering]]. In this case, the plasma parameter is given by<ref>Chen, F.F., Introduction to Plasma Physics and Controlled Fusion, (Springer, New York, 2006)</ref>:
<math display="block">\Gamma = \frac{E_\text{C}}{k_\text{B}T_\text{e}}.</math>
The Coulomb energy (per particle) is
<math display="block">E_\text{C} = \frac{q_\text{e}^2}{4\pi\varepsilon_0\langle r \rangle},</math>
where for the typical inter-particle distance <math>\langle r \rangle</math> usually is taken the [[Wigner–Seitz radius]]. Therefore,
<math display="block">\Gamma = \frac{q_\text{e}^2}{4\pi\varepsilon_0 k_\text{B}T_\text{e}}\sqrt[3]{\frac{4\pi n_\text{e}}{3}}.</math>
Clearly, up to a numeric factor of the order of unity,
<math display="block">\Gamma \sim \Lambda^{-2/3}.</math>
In general, for multicomponent plasmas one defines the coupling parameter for each species ''s'' separately:
<math display="block">\Gamma_s = \frac{q_s^2}{4\pi \varepsilon_0 k_\text{B}T_s} \sqrt[3]{\frac{4\pi n_s}{3}}.</math>
Here, ''s'' stands for either electrons or (a type of) ions.
== The ideal plasma approximation ==
One of the criteria which determine whether a collection of charged particles can rigorously be termed an [[ideal plasma]] is that {{math|Λ ≫ 1}}. When this is the case, collective electrostatic interactions dominate over binary collisions, and the plasma particles can be treated as if they only interact with a smooth background field, rather than through pairwise interactions (collisions)
▲When this is the case, collective electrostatic interactions dominate over binary collisions, and the plasma particles can be treated as if they only interact with a smooth background field, rather than through pairwise interactions (collisions) <ref>J.D. Callen, University of Wisconsin-Madison, Draft Material for Fundamentals of Plasma Physics book: Collective Plasma Phenomena [http://homepages.cae.wisc.edu/~callen/chap1.pdf PDF]</ref>. The [[equation of state]] of ideal plasma is that of [[ideal gas]].
== Plasma properties and Λ ==
{| class="wikitable" style="text-align:center"
|-
! rowspan=2 | Description
! colspan=2 | Plasma parameter magnitude
|-
! {{math|Λ ≪ 1}} ({{math|Γ ≫ 1}}) || {{math|Λ ≫ 1}} ({{math|Γ ≪ 1}})
|-
! Coupling
| Strongly coupled plasma || Weakly coupled plasma
|-
! Debye sphere
| Sparsely populated || Densely populated
|-
! Electrostatic influence
| Almost continuously || Occasional
|-
! Typical characteristic
| Cold and dense || Hot and diffuse
|- style="vertical-align:top;"
! Examples
| Solid-density laser ablation plasmas<br>Very "cold" "high pressure" arc discharge<br>Inertial fusion experiments<br>Stellar interiors
| Ionospheric physics<br>Magnetic fusion devices<br>Space plasma physics<br>Plasma ball
|}
== References ==▼
▲==References==
{{reflist}}
== External links ==
<!-- Categories -->▼
* [https://web.archive.org/web/20090325194948/http://wwwppd.nrl.navy.mil/nrlformulary/NRL_FORMULARY_07.pdf NRL Plasma Formulary 2007 ed.]
[[Category:Plasma physics| ]]▼
▲<!-- Categories -->
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