and disposal, in whole or in part by or for the United States govern-ment is permitted. By acceptance of this article, the publisher and/or recipient ac-knowledges the U.S. Government&apos;s right to retain a non-exclusive, royalty-free license in and to any copyright covering this paper. Experiments are underway on the Alcator C Tokamak with over 1 MW of RF power injected into the plasma at a frequency of 4.6 GHz to study both heating and current drive effects. During these studies, impurity genera-tion from limiter structures has been observed. The RF induced impurity influx is a strongly nonlinear function of net injected power. For Prf &lt; 500 kW, only small effects are seen. As Prf approaches 1 MW, however, sharp increases in impurity influxes and Zeff are observed. Three different lim-iter materials have been used during these studies: molybdenum, graphite, and silicon-carbide coated graphite. In each case, the materials of the limiter structure are seen to dominate the increased impurity influx. In a typical case, with Prf = 1.0 MW e = 1.3 x 1014 cm- 3, and the SiC coated limiters, Zeff is seen to increase from 1.5 before the RF pulse to about 4 during the heating. At the same time, central Te increases from 2000 eV to 3000 eV and central Ti from 1200 eV to 1800 eV. Similar effects are seen in both H2 and D2 working gas discharges. The contribution to impurity genera-tion of nonthermal electrons, which are produced by the RF, is under investi-gation. Changes in edge plasma temperature and density, as well as the possibility that the particle transport is affected by the RF, are also being examined. Results of the experiments with the three different limiter materials are compared, and contributions of impurity radiation to the overall power balance are estimated

Bombard, B.

Cool, S.

Fiore, C.

Foord, M.

Gandy, R.

Granetz, R.

Greenwald, M.

Gwinn, D.

Lipschultz, B.

Lloyd, B.

Marmar, E.S.

Moreno, J.

Pappas, D.

Parker, R.R.

Porkolab, M.

Pribyl, P.

Rice, J.

Schuss, J.

Takase, Y.

Terry, J.

Texter, S.

E. Marmar

M. Foord

B. Labombard

B. Lipschultz

J. Rice

J. Terry

B. Lloyd

M. Porkolab

Y. Takase

S. Texter

C. Fiore

M. Greenwald

D. Gwinn

S. Mccool

R. R. Parker

P. Pribyl

R. Watterson

S. Wolfe

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IMPURITY GENERATION DURING INTENSE LOWER HYBRID HEATING EXPERIMENTS ON THE ALCATOR C TOKAMAK

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PFC/JA-83-37IMPURITY GENERATION DURING INTENSE LOWER HYBRIDHEATING EXPERIMENTS ON THE ALCATOR C TOKAMAKE. Marmar, M. Foord, B. LaBombard, B. Lipschultz, J.Moreno, J. Rice, J. Terry, B. Lloyd, M. Porkolab, J.Schuss, Y. Takase, S. Texter, C. Fiore, R. Gandy, R.Granetz, M. Greenwald, D. Gwinn, S. McCool, D. Pappas,R. R. Parker, P. Pribyl, R. Watterson, and S. WolfePlasma Fusion CenterMassachusetts Institute of TechnologyCambridge, MA 02139November 1983This work was supported by the U.S. Department of Energy ContractNo. DE-AC02-78ET51013. Reproduction, translation, publication, useand disposal, in whole or in part by or for the United States govern-ment is permitted.By acceptance of this article, the publisher and/or recipient ac-knowledges the U.S. Government's right to retain a non-exclusive,royalty-free license in and to any copyright covering this paper.ABSTRACTExperiments are underway on the Alcator C Tokamak with over 1 MW of RFpower injected into the plasma at a frequency of 4.6 GHz to study bothheating and current drive effects. During these studies, impurity genera-tion from limiter structures has been observed. The RF induced impurityinflux is a strongly nonlinear function of net injected power. For Prf <500 kW, only small effects are seen. As Prf approaches 1 MW, however, sharpincreases in impurity influxes and Zeff are observed. Three different lim-iter materials have been used during these studies: molybdenum, graphite,and silicon-carbide coated graphite. In each case, the materials of thelimiter structure are seen to dominate the increased impurity influx. In atypical case, with Prf = 1.0 MW e = 1.3 x 1014 cm- 3 , and the SiC coatedlimiters, Zeff is seen to increase from 1.5 before the RF pulse to about 4during the heating. At the same time, central Te increases from 2000 eV to3000 eV and central Ti from 1200 eV to 1800 eV. Similar effects are seen inboth H2 and D2 working gas discharges. The contribution to impurity genera-tion of nonthermal electrons, which are produced by the RF, is under investi-gation. Changes in edge plasma temperature and density, as well as thepossibility that the particle transport is affected by the RF, are also beingexamined. Results of the experiments with the three different limitermaterials are compared, and contributions of impurity radiation to theoverall power balance are estimated.------- __ -------  -I. IntroductionImpurities play a role in the development of nearly all tokamak dis-charges. However, through the application of various techniques, includingdischarge cleaning (both glow and pulsed), baking and gettering, and throughjudicious choices of limiter design and materials [1], it has been generallypossible to run these devices over wide parameter ranges with only minorperturbations of plasma resistivity and power balance caused by impurities.This is especially true in the case of ohmically heated discharges. Asauxiliary input powers, particularly from various forms of RF, reach levelsof 1 MW or greater, certain presently operating devices begin to seestrong impurity effects once again. In the case of ICRF heating, the TFRexperience is one such example [2]. In this case, as RF power levelsexceed 1 MW, nickel influxes are large, resulting in most of the inputpower being radiated away. The walls, limiters and antenna faraday shieldswere all made from Inconel, and which of these structures was the mainsource of the Ni was not resolved. On the TCA device [31, Alfven waveheating, at power levels of only 90 kW, has yielded disastrous results withrespect to metal contamination of the plasma. In this case, the limiter,antenna and wall materials were stainless steel. Recent results from ICRFheating of the PLT device have been more favorable [4]. At the 1 MW level,metal densities are seen to double, but do not dominate the dischargecharacteristics, with less than 15% of the central input power being radiatedaway. Because of PLT's larger size compared to the other devices, the sur-face power loadings are, of course, lower in this case.Experiments are presently underway on the Alcator C tokamak to studycurrent drive and heating using lower hybrid RF at v = 4.6 GHz [5]. To date,- 1 -- 2 -up to 1 MW of power has been coupled into the plasma, and it is the purposeof this paper to describe the changes in impurity influxes and concentra-tions which result, particularly in the plasma heating regimes which havebeen studied. Experiments using limiters composed of molybdenum, silicon-carbide coated graphite, and bare graphite have been performed, and theresults are described below.II. Experimental ResultsThe results are grouped according to the particular limiter designin use. For Prf up to 1 MW, there have been three types of limiter used:(1) molybdenum; (2) SiC coated graphite; (3) a combination which is primar-ily Mo with graphite sections in the outer midplane. In all cases, it isthe material of the limiter which is seen to dominate the RF induced impur-ity influx. The limiters themselves are structurally similar. Each iscomposed of complete poloidal rings of small blocks attached to a stainlesssteel spine. Each ring consists of a large number of blocks, and there area total of four rings. Two rings are paired at each of two ports, theports being separated toroidally by 180 degrees. The total surface area ofthe limiters is about 1200 cm2 .II.(a) Molybdenum LimitersThe time histories of various plasma parameters during a typical LHRFheating discharge with Mo limiters are shown in figure 1. In this case thetotal forward RF power coupled into the vacuum chamber (Prf) was 950 kW.The central chord brightness at X = 75 A is indicative of Mo behavior inthe plasma. This wavelength is in the center of a pseudo-continuum [6]- 3 -which includes lines from many ionization states, up to MoXXX, and thisemission is predominantly from the regions of the plasma where 500 eV < Te< 1500 eV [7]. This is thus a good indicator of the time history of theMo density, provided that the electron density and temperature are notchanging significantly. It is clear from figure 1 that there is a largeincrease in the Mo level in the plasma during the RF pulse. The decayafter the turn off of the RF is consistent with impurity transport timesmeasured in other experiments [8]. The fifth trace in figure 1 shows thebrightness at X = 5360 A, which is due mainly to free-free bremsstrahlung.Since the emissivity is proportional to n2Zeff//-, it can be used to in-fer a "line-averaged" Zeff [9], which is shown as the last trace in thefigure. It can be seen that before the RF power is injected, Zeff = 1.5.The enhancement over 1 is due mostly to carbon in the plasma, which is thedominant low Z impurity.During the RF pulse, with the Mo limiters, the C levels do not changesignificantly, and we infer that the change in Zeff is due almost entirely tothe increased molybdenum. It is thus possible to calculate the absolute Modensity in the plasma. Although bolometric measurements of total radiatedpower were not available during these experiments, using the cooling rateformalism of Post et. al. [10], the resulting radiated power loss from theplasma due to the molybdenum can be estimated. Assuming that nMo(r)/ne(r)= constant, the result is that about 1 MW is radiated away. It must bepointed out that there are large uncertainties in this calculation. Inparticular, the cooling rates, according to the authors of reference 10, areonly accurate to about a factor of 2. A direct comparison between thebrightness at 75 A and bolometric measurements has been made, in non-RFdischarges [11]. In these cases, the cooling rate model, combined with- 4 -the Zeff measurement, predicted central radiated power densities which were25% higher than was actually observed. Using these observations as a"calibration" for the technique would imply that ~ 850 MW is radiatedduring the RF case examined here. The resultant heating is modest, with Teincreasing by about 400 eV and Ti by about 200 eV.II.(b) Silicon-Carbide Coated Graphite LimitersIn order to reduce the levels of high Z (Mo) impurities in the LHRFheated plasmas, the Mo limiters were replaced with limiters utilizingcoated graphite blocks. The coatings are chemical vapor deposited siliconcarbide, with a coating thickness of about 100 micron. The blocks werebaked in vacuum to a temperature of 900* C after coating and before beinginstalled in the tokamak. Mo levels with these limiters decreased by abouta factor of 20 to 30 when compared to similar ohmic discharges with the Molimiters. During the LHRF heating, only small increases in the Mo levelare seen (<30%). However, both Si and C levels are seen to increase sub-stantially. Figure 2 shows the time development of several plasma para-meters with Prf = 850 kW and the SiC limiters. Along with the increasesof Si and C influx, as evidenced by line radiation from ionization statesnear the edge of the plasma, strong increases of Zeff are also seen. Fig-ure 2 shows the Zeff time history for this discharge, and there is clearlya much larger perturbation to this parameter than was the case with the Molimiters. Although Zeff increases substantially, the electron temperaturealso goes up, and the net ohmic input power is not greatly increased (<15%).Te in this case, as inferred from both soft x-rays and Thomson scattering,increases from 2000 eV before the RF, to about 3000 eV during the heatingpulse. The time history of the ion temperature is also shown in figure 2,- 5 -with Ti almost doubling during the heating. It thus appears that thecentral radiation problem has been been largely alleviated, allowing forthe good heating. However, plasma purity has been seriously compromised.The increase of Zeff is a very non-linear function of Prf* Figure 3 showsthe results of a power scan with fixed ne, Ip, and Bt. Below about 500 kW,little or no effect is seen. As the power level approaches 1 MW, thechange in Zeff is seen to increase sharply.In order to investigate the effects of the increasing low Z impuritycontent on the confinement properties, experiments are being carried out toinject N2 into discharges similar to those being heated. Preliminaryresults indicate that some of the ion heating might be explained by therise in Zeff alone.II.(c) Electron TailOne of the main effects which the LHRF has on the plasma is to producea population of non-thermal electrons, with energies in the range of 20keV to over 300 keV. Figure 4 shows typical x-ray spectra, with and withoutthe RF (Mo limiter, Prf = 500 kW). At Prf = 900 kW, estimates indicate thatthe fractional population of these non thermal electrons is on the order of10-3. Since they have energies of 10 or more times the thermal, if theseelectrons are relatively poorly confined, they could account for a signifi-cant energy loss from the plasma. Furthermore, they might be expected toscrape-off in a small poloidal portion of the limiters, due to the smalloutward shift of their drift surfaces relative to the flux surfaces. Post-mortem examination of the SiC coated limiters indicates that there is indeedmuch damage in a poloidally localized region of the limiters near the outside- 6 -mid-plane. The total area affected is about 5 cm2 . If, in fact, 100 kW,or more, is carried out of the plasma by the non-thermal electrons, theresulting power loading (j 20 kW/cm2 ) would be sufficient to give rise torapid surface melting (for Mo or SiC) or sublimation (graphite). This thenmight be the major cause of the impurity generation.Supporting evidence that the impurity generation is caused by thenon-thermal electrons comes from a comparison of similar discharges, onewith good heating, and the other for unknown reasons, with little generationof non-thermals, and at the same time almost no heating, impurity generation,or rise in Zeff. Two such shots are compared in figures 5 and 6. Figure 5shows a typical case with large increases in Zeff as well as Si and C lev-els in the plasma. In this case, ATi = 800 eV. Figure 6 shows a dischargefrom the same day, where the pre-RF plasma conditions are apparently quitesimilar to those of figure 5. However, the RF appears not to have coupledas well to the electrons in this second case, with the result that there isa smaller generation of Si and C, and the AZeff is also much smaller. At thesame time ATi was only 200 eV for this shot.II.(d) Hybrid LimiterTo test further the idea that the impurities might be coming mostlyfrom the heating of the outside midplane of the limiters, a so-called"hybrid" limiter was installed into the tokamak. This limiter consists ofMo, with the exception of 4 blocks at the outside midplane each ring, whichare uncoated graphite. Initial results from this limiter show that atlevels approaching 1 MW, the effects on both Mo and C are small. Figure 7shows time histories for a typical case. Neutron rates indicate ATi =- 7 -250 eV for this discharge during the RF. Although some of the improvementin the impurity situation with this limiter might be related to the presenceof the graphite blocks on the outside midplane, the "hybrid" limiter isdifferent in another important way from the previous limiters. The damageto the SiC blocks was mostly in the radially leading 2 to 3 mm. It wastherefore decided to flatten the blocks on the "hybrid" limiter. Thedensity scrapeoff length, as measured previously with Langmuir probes, wasfound to be about 3 mm [12]. It is therefore probable that in the "hybrid"limiter, the loading is spread out over roughly 2 to 3 times the area. Itis likely that this is the main reason for the improvement with this limiter.III. DiscussionWhile non-thermal electron heating of the limiter surface is the primecandidate to explain the observed impurity effects during the LHRF experi-ments on Alcator C, other processes cannot be ruled out. Probe measurements,one cm beyond the limiter, indicate that the electron temperature increasesfrom about 5 eV before the RF, to about 7.5 eV during. These temperaturesare too low to result in significant sputtering of limiter material due toacceleration of ions across the expected sheath (- 4 x Te). Another pos-sibility is that either the RF directly, or the non-thermal electrons,affect the potential drop across the sheath at the limiters, again leadingto ion sputtering. A definitive resolution of these questions awaits fur-ther experimentation.- 8 -IV. ConclusionsLower Hybrid heating experiments on the Alcator C tokamak indicatethat as Prf approaches 1 MW, impurity effects begin to play a large role inthe evolution of the discharges. The mechanism of limiter surface heatingdue to RF produced non-thermal electrons is identified as the prime candidatewhich could explain the impurity influx. With Mo limiters, the radiated pow-er from the plasma rises dramatically, approaching a significant fractionof the total input power. With silicon carbide coated graphite limiters,efficient electron and ion heating are achieved, but at the expense ofplasma purity as reflected by an increasing Zeff. Experiments are continu-ing, both to delineate more precisely the responsible mechanisms, and, ifpossible, to reduce these impurity effects as the RF power is furtherincreased.- 9 -REFERENCES[11 G. M. McCracken and P. E. Stott, Nucl. Fusion 19 (1979) 889, andreferences therein.[21 Equipe TFR, "ICRF Results on TFR at Megawatt Power Levels", ReportEUR-CEA-FC-1108, July 1981.[3] M. F. Stamp, A. Pochelon, N. J. Peacock, J. B. Lister, B. Joye, H.Gordon, "A Spectroscopic Survey of the TCA Tokamak with and withoutLow-Frequency RF Heating", Report LRP 220/83, February 1983.[4] D. Q. Hwang, J. C. Hosea, H. R. Thompson, J. R. Wilson, et al.,"Experimental Results and Transport Simulations of ICRF Heating inPLT", proceedings of Fifth Topical Conference on Radio FrequencyPlasma Heating, Madison, Wisconsin, 1983.[5] M. Porkolab, et al., "Lower Hybrid Current Drive and Heating Experimentsup the the 1 MW Level in Alcator C," proceedings of the Fifth TopicalConference on Radio Frequency Plasma Heating, Madison, Wisconsin, 1983.And, M. Porkolab, et al., 9th Int. Conf. Plas. Res. and Contr. Nucl.Fus. Res., Baltimore, U.S.A., 1982, IAEA-CN-41/C-4.[61 W. L. Hodge, J. Castracane, H. W. Moos and E. S. Marmar, J. Quant.Spectrosc. Radiat. Transfer 27 (1982) 493.[7] James Castracane, "Grazing Incidence EUV Study of the Alcator Tokamaks",Johns Hopkins University Ph.D. thesis (1981), unpublished.[81 E. S. Marmar, J. E. Rice, J. L. Terry and F. H. Seguin, Nucl. Fusion22 (1982) 1567.[9] M. E. Foord, E. S. Marmar and J. L. Terry, Rev. Sci. Instrum. 53(1982) 1407.[101 D. E. Post, R. V. Jensen, C. B. Tarter, W. H. Grasberger and W. A.Lokke, Atomic Data and Nucl. Tables 20 (1977) 397.[11] M. M. Pickrell, "The Role of Radiation on the Power Balance of theAlcator C Tokamak," MIT Report PFC/RR-82-30, 1982.[12] A. J. Hayzen, D. 0. Overskei and J. Moreno, "Probe Measurements ofthe Boundary Plasma in Alcator C", M.I.T. Plasma Fusion Center ReportPFC/JA-81-10, April 1981.- 10 -FIGURE CAPTIONSFig. 1 Time historiesdischarge withparameters areBT = 9.3 T.of various plasma parameters for a typical heatingmolybdenum limiters. In this case, the peakIp = 400 kA, ne = 1.6 x 1014 cm- 3 , PRF = 950 kW,Fig. 2 Typical heating discharge with silicon carbide coated graphitelimiters: I = 400 kA, He = 1.7 x 1014 cm-3, pRF = 850BT = 9.3 T.Fig. 3 Power scan for A Zeff vs. PRF with SiC limiters.Fig. 4 X-ray spectrum, with and without the RF.Fig. 5 Typical good heating shot with SiC limiters. PRF = 850 kW.Fig. 6 A shot with similar plasma conditions to those of figure 5, butexhibiting small impurity effects and little heating.Fig. 7 Typical shot with "hybrid" limiter.kW,CURRENTSoo(kA)1. 5i x14(Cf 3)DENSITYRF POWERMo 75 A(A.U.)VIS BREM(A.U.)Zeff0£1100 200 300TIME (msec)FIGURE 13.0-2.01.0Soo400I I.1 Ii i-9s0 kW.... .. ... ................ .....IICURRENTDENSITYRF POWERSiT(A .U)C(A.U.)HARD X-RAY(A.U.)Za~ffI I I I100 200 300 400-1.5(keV)-1.0- 0.5S00TIME (msec)-8.50 M0I400(kA)0 1(ni~3.02.01.02.0/00,00FIGURE 2i Lw I* 4400 *4%4%4%4%04%4%0~@IIOka.0I-6LLiuJjaz VI11HFIGURE 3I %64III I I,0 e.%0*00 0 .,- 000o0(00fr~LC)rJLN-00U-)FIGURE 4.0;08.0 SS00aII~00.S- SI00~ 0IL..-SS'SaSS~09SS000.000000 c0 00.-w0Q6IL0c'jC~jC-J0dI I i I88I I I. -.,IPRF PowerVisibleContinuum(A.U.)Si Xf(A.U.)Hard X-Ray(A.UW1Zef f10r I I I100 200 300400(.kA)010I400 500TIME (msec)FIGURE 5I14 - 3I.SX10 cM-850 kW3-2-IpRF PowerVisibleContinuum(A.U.)ssi E(A.U.)Hard X-Rcy(A.U.)Zeff-0100 200TIME (300msec)00400 500FIGURE 6-850 kWIpRF Power(kW)c V(A.U.)0Mo 75 A(A.U.)V'isibleContinuum(A.U)Zeff 21-920 kWH-.0 100 200 300400)1.5X1014(crm3100400 500TIME (msec)FIGURE 7I I

Impurity generation during intense lower hybrid heating experiments on the Alcator C tokamak

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Impurity generation during intense lower hybrid heating experiments on the Alcator C tokamak

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