Instrumentation
lnductively Coupled
Plasmas Velmer A. Fassel and Richard N. Kniseley
Ames Laboratory, USAEC and Department of Chemistry Iowa State University, Ames, Iowa 50010
In the accompanying REPORT ( I ), we discussed the analytical performance of a promising new analytical system for the simultaneous determination of trace elements at the fractional microgram to nanogram level. This system is based on the observation of atomic emission spectra when samples in the form of aaaerosol, thermally generated vapor, or powder are injected into an inductively coupled plasma atomization and excitation source. In this article we discuss t h e formation and stabilization of these plasmas and their unique properties and characteristics that make them very promising atomization-excitation sources. Formation and Stabilization Inductively Coupled Plasma T o understand the nature of these plasmas, it is essential to remember three simple facts: by definition, plasmas are gases in which a significant fraction of their atoms or molecules is ionized; that being so, magnetic fields may readily interact with plasmas; and one of these interactions is an inductive coupling of time-varying magnetic fields with the plasma, analogous
of
ARGON GAS Figure 1. Inductively coupled plasma model
to the inductive heating of a metal cylinder. Referring to Figure 1,suppose we take a quartz tube approximately 2.5 cm diameter and place it inside a coil connected to a high-frequency generator operating typically in the 4-50MHz range a t generator output levels of 2-5 kW. When the generator power is turned on, nothing happens-Ar is a nonconductor. To form a plasma it is necessary to plant a “seed” of electrons in the coil space; the simplest way to do this is to “tickle” the tube with a Tesla coil. Given the proper flow pattern of Ar inside the tube, the plasma is formed spontaneously after a few popping flashes a t the open end of the tube. Let us now examine the course of events leading to the formation of the plasma. The high-frequency currents flowing in the induction coil generate oscillating magnetic fields whose lines of force are axially oriented inside the quartz tube and follow elliptical closed paths outside the coil as shown schematically in Figure 2. The induced axial magnetic fields, in turn, induce the seed of electrons and ions tz, flow in closed annular paths inside the
quartz tube space. This electron flowthe eddy current-is analogous in behavior to the current flow in a shortcircuited secondary of a transformer. If we recall that the induced magnetic fields are time-varying in their direction and strength, then we can appreciate the fact that the electrons are accelerated on each half cycle. The accelerated electrons (and ions) meet resistance to their flow, Joule or ohmic heating is a natural consequence, and additional ionization occurs. The steps just discussed lead to the almost instantaneous formation of a plasma of extended dimensions whose unique properties and characteristics make it a very promising excitation source. Thermal Isolation of Plasma
The plasma formed in this way attains a gas temperature in the 900010,OOO°K range in the region of maximum eddy current flow (2).At these temperatures it is desirable to provide some thermal isolation of the plasma to prevent overheating of the quartz containment cylinder. This isolation is achieved by Reed’s vortex stabilization technique (3,41, which utilizes a flow of argon that is introduced tan-
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the flow velocity of the carrier gas that injects the sample into the plasma. Thus, the degree to which the annular or toroidal shape is developed can be controlled by the frequency of the primary current generator and the flow velocity of the carrier gas stream. At -30 MHz, a carrier gas flow of -1 1./ min assures effective injection of sample into the plasma, if properly designed injection orifices are used. The entire torch configuration now in common use in our laboratories is shown in Figure 5 . Although efficient sample injection is achieved, the analyte does not experience the hottest part of the plasma. As the sample particles travel upstream in a rather narrow axial channel, they avoid the high-temperature doughnut, i.e., the region of maximum eddy current flow shown schematically by crosshatching in Figure 3. According to our preliminary temperature measurements, the gas temperature in the axial channel of the eddy current flow region is -7000'K. This Magnetic fields temperature is a factor of two higher currents genthan those achieved in the hottest induction coil commonly used combustion flames. Typical residence times of the sample in the plasma before the observation height is reached are about 2.5 msec. The combination of high temperatures and relatively long particle-plasma inly, causing them to be accelerated in a direction perpendicular to the exterior teraction times should lead to complete solute vaporization and a high, if surface of the plasma. The sample injection process must therefore overcome the expansion thrust of the hot gases without causing the plasma to collapse. Figure 3. Complete plasma configuraThe skin-depth effect of induction tion heating may be turned to good advantage in solving this problem. If the plasma itself is generated a t lower frequencies (-5 MHz), a teardropshaped plasma, as shown on the left portion of Figure 4,tends to be formed. Sample material that approaches the plasma tends to follow a rather disconcerting path around the outside surface. As shown in highly schematic form on the right-hand portion of Figure 4,an increase in the oscillating frequency of the power source causes the eddy current to flow more closely to the outer or skin portions of the plasma. This results from the wellknown skin-depth effect, Le., the depth a t which the eddy current declines to l l e of its maximum value near the surface is proportional to the square root of the current frequency. In this way, an incipient annular plasma shape is developed. Viewed from the bottom, the plasma has the appearance of a doughnut. Since the hole possesses a somewhat lower temperature than the doughnut, it offers less resistance to the injection of sample material. The annular shape can be further developed by optimizing r
gentially in the manner shown in Figure 3. The complete assembly of concentric quartz tubes and argon flow patterns for sustaining the plasma after it is formed is also shown in the figure. The tangential flow of argon, which is typically in the 10 l./min range for the apparatus shown, streams upward, cooling the inside walls of the outermost quartz tube and centering the plasma radially in the tube. The plasma itself is anchored near the exit end of the concentric tube arrangement. In addition to the vortex stabilization flow of Ar, there is another lower velocity flow of approximately 1l./min that transports the sample to the plasma either as an aerosol, a powder, or a thermally generated vapor. The total Ar flow required is therefore -11 1./ min. Thus, the operating cost of these plasmas, exclusive of electrical power, is approximately 50% lower than for a nitrous oxide-acetylene flame. Sample Injection into Plasma If these plasmas are to be used as efficient free-atom generators, the sample should be effectively injected into the plasma and remain in the interior high-temperature environment as long as possible. This physical condition has been difficult or impossible to attain in many plasma systems suggested for analytical purposes, and the ICP presents a problem as well ( 5 ) .In the ICP the gases are heated internal1158A
ANALYTICAL CHEMISTRY, VOL. 46, NO. 13, NOVEMBER 1974
CARBONYL
Natural Abundance 13CNMR Spectrum 0.012M HEW Lysozyme,Molecular Weight 14,314
A L I P H A T I C
Proton-decoupled natural abundance 13C spectrum of hen egg white lysozyme in 0.15M NaCl in 9 : l H 2 0 / D 2 0 ,pH 4.0, 45°C. Recorded with a TT-14 system' at 15.08 MHz using a 20 mm sample tube; 37,107 90" pulses; 4096 time-domain points; and 1.165 Hz digital line broadening. This spectrum demonstrates that in a small protein, single carbon resonances such as the one assigned above to C' in a single tyrosine residue, can be observed after only five hours of signal averaging with use of the 20 mm sample technology developed at Indiana University by Dr. Adam Allerhand.2,3 1. Sample run St the University of Chicago, courtesy of Dr. Philip Keirn, Pritzker School of Medicine. 2 . A. Allerhand R.F. Childers E. Oldfield J. Magn. Resonance 7 7 272 (1973). 3. E. Oldfield i n d A. Allerhand, Proc. Nat'. Acad. Sci. USA, 70, 353i (1973).
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not total, degree of atomization of the analyte species in the core of the plasma. Once the free atoms are formed, they occur in a chemically inert environment, as opposed to the violently reactive surroundings in combustion flames. Thus, their lifetime, on the average, should be longer than in flames. Because the quenching cross section of Ar is far less than for the molecular species found in combustion flames, these plasmas should provide a more favorable environment for attaining improved atomic fluorescence power yields. The plasma system described above possesses other unique advantages. First, after the free atoms are formed, they flow upstream in a narrow cylindrical radiating channel. The optical aperture or viewing field of conventional spectrometers can be readily filled by this narrow radiating channel. In this way, the radiating free atoms are used most effectively. Second, a t the normal height of observation, the central axial channel containing the relatively high number density of analyte free atoms has a rather uniform temperature profile. The number density of free atoms in the hot argon sheath surrounding the axial channel is far lower. Under these conditions, the analyte free atoms tend to behave as an optically thin emitting source. If a large range of emission intensities can be accommodated linearly by the measurement system, linear analytical calibration curves covering five orders
of magnitude change in concentration can be readily achieved. Thus, the variable dilutions often needed in flame spectroscopic techniques are essentially eliminated. Other advantages of these plasmas are worthy of note. No electrodes are used. Therefore, contamination from the self-electrodes normally used in other plasmas is eliminated. Because the plasma operates on nonexplosive noble gases, the systems can be used in locations where combustibles are not allowed. Description of Spectra Emitted
The plasma has the overall appearance of a very intense, brilliant white, nontransparent core and a flame-like tail. The plasma core, which resides inside and extends a few millimeters above the induction coil region, emits an intense continuum in addition to a rather fully developed spectrum of neutral argon. The continuum presumably arises from ion recombination processes and bremsstrahlen emission. Because of the high continuum emission, radiation from the plasma core has little analytical utility. The core fades into a second recognizable zone of the plasma which extends from approximately 1 to 3 cm above the induction coil. This zone is also bright but slightly transparent. In the mid-to-upper regions of this zone, the continuum emission is sharply reduced by several orders of magnitude from the core emission. Structural
Figure 5. Plasma tube dimensions
background consists of Ar lines, the
OH band emission between 260-325 nm, and weak band emission from NO, NH, CN, and Cz. In general, the highest signalhoise ratios for analyte species are observed in the second zone. The tail flame or third zone of the plasma is barely visible when distilled water is nebulized but assumes typical flame colors when analytes are added to the plasma. The axial passage of the sample aerosol and its decomposition products through the plasma is clearly visible. The above description of the emission properties of the ICP highlights another one of its distinctive advantages, namely, solute vaporization and atomization occur in the high-temperature environment of the core of the plasma, which otherwise has little utility as an emitting source for analytical purposes. The free atoms released in the core may then be observed upstream in temperature environments ranging downward from 7000'K to typical combustion flame temperatures. Typical Experimental Facilities
Figure 4. Sample particle paths for several plasma shapes 1162A
ANALYTICAL CHEMISTRY, VOL. 46, NO. 13, NOVEMBER 1974
Because of the relatively simple spectra emitted above the plasma core, low-cost, table-model spectrometers provide acceptable spectral resolution. A typical system for the sequential determination of all of the metals and metalloids is shown in Figure 6. A complete description of this
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References (1) V. A. Fassel and R. N. Kniseley, Anal. Chem.. 46 (13),.lllOA (19741, (2) A. D. Stokes, J.Phys. D: Appl. Phys., 4,916 (1971). (3) T. B. Reed, J. Appl. Phys., 32,821, 2534 (1961). (4) T. B. Reed, Int.Sci. Teehnol., 42 (June 1962). ( 5 ) V. A. Fassel, "Electrical Plasma
Soeetraseoov." XVI Colloquium Spectroseo$&m Internatibnale, Adam Hilger, London, England, 1973. ( 6 ) R. H. Scott, V. A. Fassel, R. N. Kniseley, and D. E. Nixon, Anal. Chem., 46.75 (1974).
( 7 ) K. W. Busch and G. H. Morrison, ibid., 45,712A (1973).
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