Inductively coupled plasma

Fig. 1. Picture of an analytical ICP torch

An inductively coupled plasma (ICP) or transformer coupled plasma (TCP)^[1] is a type of plasma source in which the energy is supplied by electric currents which are produced by electromagnetic induction, that is, by time-varying magnetic fields.^[2]

Operation

Fig. 2. The construction of Inductively Coupled Plasma torch.^[3] A: cooling gas tangential flow to the outer quartz tube B: discharge gas flow (usually Ar) C: flow of carrier gas with sample D: induction coil which forms the strong magnetic field inside the torch E: force vectors of the magnetic field F: the plasma torch (the discharge).

There are three types of ICP geometries: planar (Fig. 3 (a)), cylindrical ^[4] (Fig. 3 (b)), and half-toroidal (Fig. 3 (c)).^[5]

Fig. 3. Conventional Plasma Inductors

In planar geometry, the electrode is a length of flat metal wound like a spiral (or coil). In cylindrical geometry, it is like a helical spring. In half-toroidal geometry, it is toroidal solenoid cut along its main diameter to two equal halves.

When a time-varying electric current is passed through the coil, it creates a time-varying magnetic field around it, with flux

${\displaystyle \Phi =\pi r^{2}H=\pi r^{2}H_{0}\cos \omega t}$,

where r is the distance to the center of coil (and of the quartz tube).

According to the Faraday–Lenz's law of induction, this creates azimuthal electromotive force in the rarefied gas:

${\displaystyle U=-{\frac {d\Phi }{dt}}}$,

which corresponds to electric field strengths of

${\displaystyle E={\frac {U}{2\pi r}}={\frac {\omega rH_{0}}{2}}\sin \omega t}$,^[6]

leading to the formation of the figure-8 electron trajectories^[5] providing a plasma generation. The dependence on r suggests that the gas ion motion is most intense in the outer region of the flame, where the temperature is the greatest. In the real torch, the flame is cooled from the outside by the cooling gas, so the hottest outer part is at thermal equilibrium. There temperature reaches 5 000–6 000 K.^[7] For more rigorous description, see Hamilton-Jacobi equation in electromagnetic fields.

The frequency of alternating current used in the RLC circuit which contains the coil usually 27–41 MHz. To induce plasma, a spark is produced at the electrodes at the gas outlet. Argon is one example of a commonly used rarefied gas. The high temperature of the plasma allows the determination of many elements, and in addition, for about 60 elements degree of ionization in the torch exceeds 90 %. The ICP torch consumes ca. 1250–1550 W of power, but this depends on the elemental composition of the sample (due to different ionization energies).^[7]

Applications

Plasma electron temperatures can range between ~6 000 K and ~10 000 K (~6 eV - ~100 eV),^[5] comparable to the surface of the sun. ICP discharges are of relatively high electron density, on the order of 10¹⁵ cm⁻³. As a result, ICP discharges have wide applications where a high-density plasma (HDP) is needed.

• ICP-AES, a type of atomic emission spectroscopy.
• ICP-MS, a type of mass spectrometry.
• ICP-RIE, a type of reactive-ion etching.
• Exciting a beam of noble gas to the metastable state.^[8]

Another benefit of ICP discharges is that they are relatively free of contamination, because the electrodes are completely outside the reaction chamber. By contrast, in a capacitively coupled plasma (CCP), the electrodes are often placed inside the reactor and are thus exposed to the plasma and subsequent reactive chemical species.

See also

• Pulsed inductive thruster
• Induction plasma technology
• List of plasma (physics) articles
• Capacitively coupled plasma

References

1. High density fluorocarbon etching of silicon in an inductively coupled plasma: Mechanism of etching through a thick steady state fluorocarbon layer T. E. F. M. Standaert, M. Schaepkens, N. R. Rueger, P. G. M. Sebel, and G. S. Oehrleinc
2. A. Montaser and D. W. Golightly, eds. (1992). Inductively Coupled Plasmas in Analytical Atomic Spectrometry. VCH Publishers, Inc., New York,. {{cite book}}: |author= has generic name (help)
3. Lajunen, L. H. J.; Perämäki, P. (2004). Spectrochemical Analysis by Atomic Absorption and Emission (2 ed.). Cambridge: RSC Publishing. p. 205. ISBN 978-0-85404-624-9.
4. Pascal Chambert and Nicholas Braithwaite (2011). Physics of Radio-Frequency Plasmas. Cambridge University Press, Cambridge. pp. 219–259. ISBN 978-0521-76300-4.
5. Shun'ko, Evgeny V.; Stevenson, David E.; Belkin, Veniamin S. (2014). "Inductively Coupling Plasma Reactor With Plasma Electron Energy Controllable in the Range From ~6 to ~100 eV". IEEE Transactions on Plasma Science. 42 (3): 774–785. Bibcode:2014ITPS...42..774S. doi:10.1109/TPS.2014.2299954. ISSN 0093-3813.
6. Бабушкин, А. А.; Бажулин, П. А.; Королёв, Ф. А.; Левшин, Л. В.; Прокофьев, В. К.; Стриганов, А. Р. (1962). "Эмиссионный спектральный анализ". In Гольденберг, Г. С. (ed.). Методы спектрального анализа. Москва: Издательство МГУ. p. 58.
7. Dunnivant, F. M.; Ginsbach, J. W. (2017). Flame Atomic Absorbance and Emission Spectrometry and Inductively Coupled Plasma — Mass Spectrometry. Whitman College. Retrieved 10 January 2018.
8. Ben Ohayon, Erik Wahlin and Guy Ron (2015). "Characterization of a metastable neon beam extracted from a commercial RF ion source". Journal of Instrumentation. 10 (3): P03009. arXiv:1502.05376. Bibcode:2015JInst..10P3009O. doi:10.1088/1748-0221/10/03/P03009.