Townsend discharge

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The Townsend discharge is a gas ionisation process where an initially very small amount of free electrons, accelerated by a sufficiently strong electric field, give rise to electrical conduction through a gas by avalanche multiplication: when the number of free charges drops or the electric field weakens, the phenomena ceases. It is a process characterized by very low current densities: in common gas filled tubes, typical magnitude of currents flowing during this process range from about 10 − 18A to about 10 - 5A, while applied voltages are almost constant. Subsequent transition to ionisation processes of dark discharge, glow discharge, and finally to arc discharge are driven by increasing current densities: in all these discharge regimes, the basic mechanism of conduction is avalanche breakdown. Townsend discharge is named after John Sealy Townsend.

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[edit] Quantitative description of the phenomena

The basic set-up of the experiments investigating ionisation discharges in gases consist of a plane parallel plate capacitor filled with a gas and a continuous current high voltage source connected between its terminals: the terminal at the lower voltage potential is named cathode while the other is named anode. Forcing the cathode to emit electrons (eg. by irradiating it with a X-ray source), Townsend found that the current I flowing into the capacitor depends on the electric field between the plates in such a way that gas ions seems to multilply as they moved between them. He observed currents varying over ten or more orders of magnitude while the applied voltage was virtually constant: the experimental data obtained from his (and his school) first experiments is described by the following formula

\frac{I}{I_0}=e^{\alpha_n d}

where

  • I\, is the current flowing in the device
  • I_0\, is the photoelectric current generated at the cathode surface
  • \alpha_n\, is the first Townsend ionisation coefficient, expressing the number of ion pairs generated per unit length (e.g. meter) by a negative ion (anion) moving from cathode to anode
  • d\, is the distance between the plates of the device

The almost constant voltage between the plates is equal to the breakdown voltage needed to create a self-sustaining avalanche: it decreases when the current reaches the glow discharge regime. Subsequent experiments revealed that the current I rises faster than predicted by the above formula as the distance d increases: two different effects were considered in order to explain the physics of the phenomena and to be able to do a precise quantitative calculation.

[edit] Gas ionisation caused by motion of positive ions

Townsend put forward the natural hypotesis that also positive ions produce ion pairs, introducing a coefficient αp expressing the number of ion pairs generated per unit length by a positive ion (cation) moving from cathode to anode. The following formula was found

\frac{I}{I_0}=\frac{(\alpha_n-\alpha_p)e^{(\alpha_n-\alpha_p)d}}{\alpha_n-\alpha_p e^{(\alpha_n-\alpha_p)d}}  \qquad\Longrightarrow\qquad \frac{I}{I_0}\cong\frac{e^{\alpha_n d}}{1 - {\alpha_p/\alpha_n} e^{\alpha_n d}}

since β < < α, in very good agreement with experiments.

[edit] Cathode emission caused by impact of ions

Townsend and Holst and Oosterhuis also put forward an alternative hypothesis, considering augmented emission of electrons by cathode caused by positive ions impact, introducing the coefficient εi, the average number of electrons released from a surface by an incident positive ion, and working out the following formula:

\frac{I}{I_0}=\frac{e^{\alpha_n d}}{1 - {\epsilon_i}\left(e^{\alpha_n d}-1\right)}

These two formulas may be thought as describing limiting cases of the effective behavior of the process: note that they can be used to well describe the same experimental results. Other formulas describing, various intermediate behaviors, are found in the literature, particularly in reference 1 and citations therein.

[edit] Applications

Neon lamp/cold-cathode gas diode relaxation oscillator
Neon lamp/cold-cathode gas diode relaxation oscillator
f\cong\frac{1}{R1C1\ln\frac{V1-V_{GLOW}}{V1-V_{TWN}}}
where
Since temperature and time stability of the characteristics of gas diodes and neon lamps is low, and also the statistical dispersion of breakdown voltages is high, the above formula can only give a qualitative indication of what the real frequency of oscillation is.

[edit] See also

[edit] References

  • S. Flügge (edited by) (1956). Handbuch der Physik/Encyclopedia of Physics band/volume XXI - Electron-emission • Gas discharges I. Springer-Verlag.  First chapter of the article Secondary effects by P.F. Little.
  • James W Gewartowski and Hugh Alexander Watson (1965). Principles of Electron Tubes: Including Grid-controlled Tubes, Microwave Tubes and Gas Tubes. D. Van Nostrand Co, Inc.. 
  • Herbert J. Reich (1939,1944). Theory and applications of electron tubes. McGraw-Hill Co, Inc..  Chapter 11 "Electrical conduction in gases" and chapter 12 "Glow- and Arc-dischrage tubes and circuits".