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| un:plasma [2024/09/18 05:19] – created asad | un:plasma [2024/10/06 13:29] (current) – [4. Plasma Theory] asad | ||
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| ====== Plasma ====== | ====== Plasma ====== | ||
| - | //A plasma is a gas of charged particles containing an equal number of **free** positive and negative charge carriers.// It behaves in a // | ||
| + | Earlier the subject of geophysics was mainly the Earth' | ||
| + | Plasma is an ionized gas of charged particles with an equal number of free positive and negative charge carriers. For this reason plasma is considered quasineutral at stationary state. From the outside it looks neutral. A free particle is one whose kinetic energy is greater than its potential energy. Because of this the temperature of the plasma is also high, because temperature is a measure of kinetic energy. | ||
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| + | ===== - Debye shielding ===== | ||
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| + | In order for the plasma to be quasineutral at stationary conditions, the charges of the particles on the microscopic scale must cancel out such that the gas appears neutral on the macroscopic scale. Coulomb potential at a distance $r$ from a charge $q$ | ||
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| + | $$ \phi_C = \frac{q}{4\pi\epsilon_0 r} $$ | ||
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| + | where $\epsilon_0$ is the permittivity in free space. It must be shielded so that the potential of other charges does not fall within this potential. This shielded potential is called the Debye potential, mathematically | ||
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| + | $$ \phi_D = \frac{q}{4\pi\epsilon_0 r} e^{-r/ | ||
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| + | where $\lambda_D$ is the Debye length. Beyond the Debye length of a charge, i.e., if $r > \lambda_D$ , the potential decreases exponentially. Thermal kinetic energy tends to reduce neutrality, electrostatic potential energy tends to restore neutrality, and a balance between these two energies occurs at the Debye length. Debye length | ||
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| + | $$ \lambda_D = \left(\frac{\epsilon_0 k_B T_e}{n_e e^2}\right)^{1/ | ||
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| + | where $k_B$ is the Boltzmann constant, $e$ is the electron charge, $T_e$ is the electron temperature equal to the ion temperature $T_i$, $n_e$ is the electron density equal to the ion density $n_i$. The definition of temperature can be more exact, but we will assume this relationship between average energy and temperature for now: $\langle E \rangle = k_B T$ . | ||
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| + | To be quasineutral, | ||
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| + | [[https:// | ||
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| + | This figure compares Coulomb and Debye potentials in nanovolt units. The distance on the x axis is given in proportion to the Debye length. As can be seen, the Debye potential (orange) approaches zero much faster than the Coulomb potential (blue) beyond the Debye length. | ||
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| + | ===== - Plasma parameters ===== | ||
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| + | A Debye sphere can be thought of with a radius of Debye length. In order to form a plasma, this sphere must contain a sufficient number of particles. The volume of the sphere $(4\pi/ | ||
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| + | $$ N = \frac{4\pi}{3} \lambda_D^3 n_e $$ | ||
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| + | where $\Lambda = \lambda_D^3 n_e$ is called the plasma parameter. This is where the **Second Plasma Criterion** comes from: | ||
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| + | $$ \Lambda \gg 1 $$ | ||
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| + | That is, the total number of particles must be much greater than one. Substituting the full form of the Debye length into this equation gives | ||
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| + | $$ n_e^{1/3} \ll k_B T_e $$ | ||
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| + | Which clarifies the meaning of the second criterion. Since the potential energy is proportional to the electron density above, the mean potential energy must be much less than the mean energy $\langle E \rangle$ . | ||
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| + | ===== - Plasma frequency ===== | ||
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| + | When a quasineutral plasma is disturbed from outside, its electrons tend to return to their previous neutral state. The speed of the electron rather than the ion is being referred to because the electron is much lighter than other ions. External disturbances cause an average oscillation in plasma electrons around relatively massive ions. The frequency of this oscillation is called the plasma frequency, mathematically | ||
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| + | $$ \omega_{pe} = \left(\frac{n_e e^2}{m_e \epsilon_0} \right)^{1/ | ||
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| + | where $m_e$ is the mass of the electron. The basic lesson of this equation is that the plasma frequency is proportional to the square root of the electron density. | ||
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| + | A plasma like that of the Earth' | ||
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| + | $$ \omega_{pe} \tau_n \gg 1 $$ | ||
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| + | where $\tau_n$ is the average time between two collisions between an electron and a neutral. The bottom line is this: the plasma frequency must be much higher than the collision frequency. | ||
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| + | ===== - Plasma Theory ===== | ||
| + | Plasma dynamics refers to the interaction of electric and magnetic fields with different types of charge carriers. Space plasmas have many external influences as well as many influences inside the plasma, making its dynamics very complex. To create its perfect mathematical model, the equations of motion for each particle must be known, and since each particle is affected by all the other particles, the equations for all particles must be simultaneously. This is practically impossible and unnecessary, | ||
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| + | //Single Particle Motion// is the simplest approach. Here only the effect of external electric and magnetic fields on an individual particle is considered. Here the overall behavior of the plasma is neglected. But this approach is sufficient to explain the type of low-density plasma found in ring currents. | ||
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| + | // | ||
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| + | The // | ||
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| + | //Kinetic theory// is the most advanced approach, as statistics are well used here. A variety of statistical distribution functions in phase space are used instead of equations of motion for individual particles. | ||
un/plasma.1726658365.txt.gz · Last modified: 2024/09/18 05:19 by asad