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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 by the cooling gas from the outside , so the hottest outer part is at thermal equilibrium. Temperature there reaches 5 000 – 6 000 K. For
75:
Fig. 2. The construction of
Inductively Coupled Plasma torch. 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
359:
which contains the coil is 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 atomization of molecules and thus determination of many elements, and in
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can range between ~6,000 K and ~10,000 K and are usually several orders of magnitude greater than the temperature of the neutral species. Temperatures of argon ICP plasma discharge are typically ~5,500 to 6,500 K and are therefore comparable to those reached at the surface
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384:) of the sun (~4,500 K to ~6,000 K). ICP discharges are of relatively high electron density, on the order of 10 cm. As a result, ICP discharges have wide applications wherever a high-density plasma (HDP) is needed.
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addition, for about 60 elements the degree of ionization in the torch exceeds 90%. The ICP torch consumes c. 1250–1550 W of power, and this depends on the element composition of the sample (due to different
179:
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The ICPs have two operation modes, called capacitive (E) mode with low plasma density and inductive (H) mode with high plasma density. Transition from E to H heating mode occurs with external inputs.
252:
558:
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".
609: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.).
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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
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471:
High density fluorocarbon etching of silicon in an inductively coupled plasma: Mechanism of etching through a thick steady state fluorocarbon layer
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432:(CCP), the electrodes are often placed inside the reactor chamber and are thus exposed to the plasma and to subsequent reactive chemical species.
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In planar geometry, the electrode is a length of flat metal wound like a spiral (or coil). In cylindrical geometry, it is like a
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When a time-varying electric current is passed through the coil, it creates a time-varying magnetic field around it, with flux
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There are three types of ICP geometries: planar (Fig. 3 (a)), cylindrical (Fig. 3 (b)), and half-toroidal (Fig. 3 (c)).
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Hyo-Chang Lee (2018) Review of inductively coupled plasmas: Nano-applications and bistable hysteresis physics 5 011108
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leading to the formation of the electron trajectories providing a plasma generation. The dependence on
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Flame Atomic
Absorbance and Emission Spectrometry and Inductively Coupled Plasma — Mass Spectrometry
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T. E. F. M. Standaert, M. Schaepkens, N. R. Rueger, P. G. M. Sebel, and G. S. Oehrleinc
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333:{\displaystyle E={\frac {U}{2\pi r}}={\frac {\omega rH_{0}}{2}}\sin \omega t}
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is the distance to the center of coil (and of the quartz tube).
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Inductively
Coupled Plasmas in Analytical Atomic Spectrometry
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174:{\displaystyle \Phi =\pi r^{2}H=\pi r^{2}H_{0}\cos \omega t}
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534:. Cambridge University Press, Cambridge. pp. 219–259.
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Spectrochemical
Analysis by Atomic Absorption and Emission
509:(2 ed.). Cambridge: RSC Publishing. p. 205.
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530:Pascal Chambert and Nicholas Braithwaite (2011).
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490:A. Montaser and D. W. Golightly, ed. (1992).
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95:spring. In half-toroidal geometry, it is a
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627:Dunnivant, F. M.; Ginsbach, J. W. (2017).
23:Fig. 1. Picture of an analytical ICP torch
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505:Lajunen, L. H. J.; Perämäki, P. (2004).
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613:. Москва: Издательство МГУ. p. 58.
247:{\displaystyle U=-{\frac {d\Phi }{dt}}}
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87:Fig. 3. Conventional Plasma Inductors
560:IEEE Transactions on Plasma Science
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686:Plasma technology and applications
532:Physics of Radio-Frequency Plasmas
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653:https://doi.org/10.1063/1.5012001
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348:more rigorous description, see
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611:Методы спектрального анализа
402:atomic emission spectroscopy
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447:Induction plasma technology
442:Capacitively coupled plasma
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430:capacitively coupled plasma
352:in electromagnetic fields.
59:, that is, by time-varying
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37:transformer coupled plasma
29:inductively coupled plasma
452:Pulsed inductive thruster
57:electromagnetic induction
580:10.1109/TPS.2014.2299954
350:Hamilton–Jacobi equation
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55:which are produced by
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476:2016-02-07 at the
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633:. Whitman College
516:978-0-85404-624-9
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681:Ion source
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637:10 January
458:References
588:0093-3813
325:ω
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297:ω
282:π
231:Φ
222:−
197:azimuthal
166:ω
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137:π
118:π
112:Φ
67:Operation
596:34765246
474:Archived
436:See also
204:rarefied
568:Bibcode
418:ICP-RIE
398:ICP-AES
389:ICP-OES
375:Plasma
202:in the
93:helical
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184:where
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592:S2CID
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