Plasma parameters

(Redirected from Ion gyrofrequency)

Plasma parameters define various characteristics of a plasma, an electrically conductive collection of charged and neutral particles of various species (electrons and ions) that responds collectively to electromagnetic forces.[1] Such particle systems can be studied statistically, i.e., their behaviour can be described based on a limited number of global parameters instead of tracking each particle separately.[2]

Fundamental

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The fundamental plasma parameters in a steady state are

  • the number density   of each particle species   present in the plasma,
  • the temperature   of each species,
  • the mass   of each species,
  • the charge   of each species,
  • and the magnetic flux density  .

Using these parameters and physical constants, other plasma parameters can be derived.[3]

Other

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All quantities are in Gaussian (cgs) units except energy and temperature which are in electronvolts. For the sake of simplicity, a single ionic species is assumed. The ion mass is expressed in units of the proton mass,   and the ion charge in units of the elementary charge  ,   (in the case of a fully ionized atom,   equals to the respective atomic number). The other physical quantities used are the Boltzmann constant ( ), speed of light ( ), and the Coulomb logarithm ( ).

Frequencies

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  • electron gyrofrequency, the angular frequency of the circular motion of an electron in the plane perpendicular to the magnetic field:  
  • ion gyrofrequency, the angular frequency of the circular motion of an ion in the plane perpendicular to the magnetic field:  
  • electron plasma frequency, the frequency with which electrons oscillate (plasma oscillation):  
  • ion plasma frequency:  
  • electron trapping rate:  
  • ion trapping rate:  
  • electron collision rate in completely ionized plasmas:  
  • ion collision rate in completely ionized plasmas:  

Lengths

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  • electron thermal de Broglie wavelength, approximate average de Broglie wavelength of electrons in a plasma:  
  • classical distance of closest approach, also known as "Landau length" the closest that two particles with the elementary charge come to each other if they approach head-on and each has a velocity typical of the temperature, ignoring quantum-mechanical effects:  
  • electron gyroradius, the radius of the circular motion of an electron in the plane perpendicular to the magnetic field:  
  • ion gyroradius, the radius of the circular motion of an ion in the plane perpendicular to the magnetic field:  
  • plasma skin depth (also called the electron inertial length), the depth in a plasma to which electromagnetic radiation can penetrate:  
  • Debye length, the scale over which electric fields are screened out by a redistribution of the electrons:  
  • ion inertial length, the scale at which ions decouple from electrons and the magnetic field becomes frozen into the electron fluid rather than the bulk plasma:  
  • mean free path, the average distance between two subsequent collisions of the electron (ion) with plasma components:   where   is an average velocity of the electron (ion) and   is the electron or ion collision rate.

Velocities

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  • electron thermal velocity, typical velocity of an electron in a Maxwell–Boltzmann distribution:  
  • ion thermal velocity, typical velocity of an ion in a Maxwell–Boltzmann distribution:  
  • ion speed of sound, the speed of the longitudinal waves resulting from the mass of the ions and the pressure of the electrons:   where   is the adiabatic index
  • Alfvén velocity, the speed of the waves resulting from the mass of the ions and the restoring force of the magnetic field:
      in cgs units,
      in SI units.

Dimensionless

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  • number of particles in a Debye sphere  
  • Alfvén speed to speed of light ratio  
  • electron plasma frequency to gyrofrequency ratio  
  • ion plasma frequency to gyrofrequency ratio  
  • thermal pressure to magnetic pressure ratio, or beta, β  
  • magnetic field energy to ion rest energy ratio  

Collisionality

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In the study of tokamaks, collisionality is a dimensionless parameter which expresses the ratio of the electron-ion collision frequency to the banana orbit frequency.

The plasma collisionality   is defined as[4][5]   where   denotes the electron-ion collision frequency,   is the major radius of the plasma,   is the inverse aspect-ratio, and   is the safety factor. The plasma parameters   and   denote, respectively, the mass and temperature of the ions, and   is the Boltzmann constant.

Electron temperature

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Temperature is a statistical quantity whose formal definition is   or the change in internal energy with respect to entropy, holding volume and particle number constant. A practical definition comes from the fact that the atoms, molecules, or whatever particles in a system have an average kinetic energy. The average means to average over the kinetic energy of all the particles in a system.

If the velocities of a group of electrons, e.g., in a plasma, follow a Maxwell–Boltzmann distribution, then the electron temperature is defined as the temperature of that distribution. For other distributions, not assumed to be in equilibrium or have a temperature, two-thirds of the average energy is often referred to as the temperature, since for a Maxwell–Boltzmann distribution with three degrees of freedom,  .

The SI unit of temperature is the kelvin (K), but using the above relation the electron temperature is often expressed in terms of the energy unit electronvolt (eV). Each kelvin (1 K) corresponds to 8.617333262...×10−5 eV; this factor is the ratio of the Boltzmann constant to the elementary charge.[6] Each eV is equivalent to 11,605 kelvins, which can be calculated by the relation  .

The electron temperature of a plasma can be several orders of magnitude higher than the temperature of the neutral species or of the ions. This is a result of two facts. Firstly, many plasma sources heat the electrons more strongly than the ions. Secondly, atoms and ions are much heavier than electrons, and energy transfer in a two-body collision is much more efficient if the masses are similar. Therefore, equilibration of the temperature happens very slowly, and is not achieved during the time range of the observation.

See also

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References

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  1. ^ Peratt, Anthony, Physics of the Plasma Universe (1992);
  2. ^ Parks, George K., Physics of Space Plasmas (2004, 2nd Ed.)
  3. ^ Bellan, Paul Murray (2006). Fundamentals of plasma physics. Cambridge: Cambridge University Press. ISBN 0521528003.
  4. ^ Nucl. Fusion, Vol. 39, No. 12 (1999)
  5. ^ Wenzel, K and Sigmar, D.. Nucl. Fusion 30, 1117 (1990)
  6. ^ Mohr, Peter J.; Newell, David B.; Taylor, Barry N.; Tiesenga, E. (20 May 2019). "CODATA Energy conversion factor: Factor x for relating K to eV". The NIST Reference on Constants, Units, and Uncertainty. National Institute of Standards and Technology. Retrieved 11 November 2019.