In order to benchmark and improve current 2D radiation magnetohydrodynamic (MHD) models of Z-pinch plasmas, we have performed experiments which characterize the plasma -conditions at stagnation. In the experiments the SATURN pulsed power facility at Sandia National Laboratory was used to create an imploding -Ar-Ne plasma. An absolutely calibrated, high resolution space- and time- resolving Johann crystal spectrometer was used to infer the electron temperature Te from the slope of the hydrogenlike Ne free-bound continuum, and the ion density ni from the Stark broadening of the Ar heliunlike Rydberg series. 2D electron temperature profiles of the plasma are obtained from a set of imaging crystals also focused on the Ne free-bound continuum. We shot two types of gas nozzles in the experiment, annular and uniform fill which varies the amount of mass in the plasma. 2D local thermodynamic equilibrium (LTE) and non-LTE MM models predict a radiating region denser and cooler than measured

Bruns, H. C.

Deeney, C.

Emig, J. A.

Foord, M. E.

Hammer, J. H.

Iglesias, C. A.

Osterheld, A. L.

Springer, P. T.

Wong, K. L.

UNT Digital Library

—UCRL-JC- 125430PREPRINTOne- and Two-Dimensional Density and TemperatureMeasurements of an Argon-Neon Z-Pinch Plasma atStagnationK. L. Wong, P. T. Springer, J. H. Hammer, C. A. Iglesias,A. L. Osterheld, M. E. Foord, H. C. Bruns, J. A. Emig, C. DeeneyThis paper was prepared for submittal to the14th International Conference on the Application of Accelerators in Research and IndustryDenton, TXNovember 6-9, 1996DISCLAIMERThis document was prepared as an account of work sponsored by an agency ofthe United States Government.  Neither the United States Government nor theUniversity of California nor any of their employees, makes any warranty, expressor implied, or assumes any legal liability or responsibility for the accuracy,completeness, or usefulness of any information, apparatus, product, or processdisclosed, or represents that its use would not infringe privately owned rights.Reference herein to any specific commercial product, process, or service by tradename, trademark, manufacturer, or otherwise, does not necessarily constitute orimply its endorsement, recommendation, or favoring by the United StatesGovernment or the University of California.  The views and opinions of authorsexpressed herein do not necessarily state or reflect those of the United StatesGovernment or the University of California, and shall not be used for advertisingor product endorsement purposes.i“. .ONE- AND TWO-DIMENSIONAL DENSITY AND TEMPERATUREMEASUREMENTS OF AN ARGON-NEON Z-PINCH PLASMA ATSTAGNATIONK L. Wong, P. T. Springer, J. H. Hammer, C. A. Iglesias, A. L. Osterheld, M. E. Foord, H. C.Bruns, J. A. EmigLawrence Livermore National .hboratoty, Livermore, California 94551C. DeeneySandia National Laboratory, Albuquerque, New Mexico 87185In order to benchmark and improve current 2D radiation magnetohydrodynmnic (MI-ID) models of Z-pinchplasmas, we have performed experiments which characterize the plasma conditions at stagnation In theexperiments the SATURN puked power facility at Sandia National Laboratmy was used to create an imploding&-Ne plasma. An absolutely ealibmt@ high resolution space- and time-resolving Johann crystal spectrometerwas used to infer the electron temperature Te from h slope of the hydrogerdike Ne &e-bound eontinu~ andthe ion density ni from the Stark broadening of the Ar heliuxnlike Rydberg series. 2D eleetron temprmtureprofiles of the plasma are obtained from a set of imaging crystals also foeussed on the Ne free-boundcontinuum. We shot two types of gas nozzles in the experimen~ annular and uniform fillj which varies theamount of mass in the Plasma. 2D local thermodynamic equilibrium (LTE) and non-LlT3 MHD models Dre&ta radiating region den.& and cooler than measdINTRODUCTIONZ-pinch accelerators have been used for many years as x-ray sources (P > 1 TW, E < 3 keV, t - 40 ns) forapplications such as materials testing and x-ray lithographyand rnicroseopy(l). However, due to the complexity of thepinch dynamics these sources have not been modeled fromfirst principles. Furthermore, direct comparison withexperiment has been di.ffkult beeause of a lack of highprecision data (poor resolution, time integratingspeetrometers). Therefore, there is clearly a need for highresolutioxL time-gated diagnostics which can be used to testcurrent 2D radiation MHD models(2).In this paper we present the first high-resolutio~ time-resolved measurements of a Z-pinch plasma. The purposeof this experiment was to provide high quality data on theplasma conditions to compare with models. The goalwould be to provide a predictive capability in order tooptimize x-ray output and to scale the output to larger futuresources.EXPERIMENTThe SATURN accelerator located at Sandia NationalLaboratory in Albuquerque, NM(3) was the x-ray sourceused in the experiment. The peak power of the generatorwas 15 TW. Hot Ne-Ar plasmas are formed by injecting600 ~g annular or 200 ~g uniform 90’%.Ne-10% Ar neutral- gas columns into the 5 x 10-5 torr vacuum between theanode and cathode of the device. A pair of UV flashboardspreionize the gas, and SATURN is fired 1 ps later whichdelivers -8 MA at 1.9 MV to the load. The J X B force. . .eases the plasma to implode at v = 108 cmk. The plasmastagnates or nxtches & eyliical axis in 60-90 ns, and aburst of x-mys is released as the plasma kinetic energy istransferred to x-mys.A high resolution space- and time-resolving Johanncrystal speertometer was used to monitor the x-rays in theexperiment. The spectrometer is equipped with three 100pm verticrd inaging slits which xadially image the sourcewith a magni.tleation of 1.7. The data wem taken using thespectrometer with four separate c@als. We used 10 cmlong ADP(101) and quartz(l 120) crystals with latticespacings of 2d = 10.64A and4.912 A, ~speetively. Thecrystals were bent to radii of curvature of 50 cm and the x-rays were spectrally dispersed and focussed at the 25 cmRowland circle radius. The nxolving power of the setup isE/AE = 3000. The spectrometer was set to a nominalBragg angle of 40”. The total x-ray energy range coveredwas 1.6-2.0 keV for the ADP crystal and 3.4-4.4 keV forthe quartz cxystal. In order to obtain 2D images of theplasma we used 1 cm long ADP(101) and quartz(l 120)crystals bent to radii of eurvatute of 88 cm. Crystals bent ‘to this radius produce monochromatic images of the pkasmaat the 25 cm Rowland circle in the spectrrd direetiom TheBragg angles for the ADP and quartz crystals were setindependently to 35” and 42.5”, respectively. The ADPand quartz imaging crystals had a demagn~lcation of 7.7and 4.6, repeetively in the axial direetion. A schematic ofthe experimental setup is shown in Fig. 1. We record the x-rays on a twodimensional gated microchannel plate (MCP)detector with three active striplines which can be biased todifferent voltages coupled to a phosphor coated fiber opticplate. The MCP, coated with a Au photoeathode, is activefor 1 ns of the typical 40 m x-ray pulse of SATURN. TheArqon He-likeRyd6erg seri2D monochromaticimageGated microchannelA\plate detector , ~&7A Z-pinch rdasma RowlandNeon free-bound)!=~/1continuum (3.44.4 kev)., ..*~$.,>:... _;+.:;.>......I_ * at 3.73 keV2D monochromaticimages of neonfree-boundcontinuumeat 2.03 keV100 pm radialimaging slit‘ W,zm:;;z-z.r ● Spectrally2D imaging crystsfs dispersedc Radiily imaged ● F&.50cm● Speetralfy imaged● ~=aScm .FIGURE 1. Schematicdrawing of the experimentalsetup.data were recorded on Kodak optical Th4AX fti. A He-like(l-3), He-lilm(l+, and H-like(l-3). The lines on themicrodensitometer was used to meastm the fti optical middle strip illuminated by the quartz crystal are the He-density vemus position Each piece of fti was developed and H-like Ar Rydberg series. We mesure form the He-with a preexposed calibrated step wedge to convert optical like(l-3) to the He-liie(l-9) and fmm the H-like(l-3) to thedensity to x-ray expsure. H-like(l-9). Superimposed on the Rydberg series is theFig. 2 shows a typical piece of film data from an Ar-Ne hydrogenlike neon fro-bound continuum radiation fromshot.. The broad band exposute running across the top strip 3.44.4 keV. The bottom strip shows the monochromaticfrom the ADP crystal is radiation due to xecombirtationonto 2D imagesof the plasma from the ADP (left) and the quatzbare neon ions resulting in the hydrogerdike free-bound (right) crystals of the hydrogerdike neon-free boundcontinuum from 1.6-2.0 keV. The bright lines running continuum at 2.03 keV and 3.73 keV, respectively.vertically on the strip are 2nd order Ar Rydberg series lineseContiuurnFXGURE2. A typical piece of tilm data showing radiallyresolvd Sp@mof an 10% Ar- 90% Ne z-pinch plasma in the top twostrips. The bottom strip shows two-dimensional monochromaticimages of the plasma.1. . .3 H 1-3He 1-4&1-H 1-4He 1-5II [ H 1-5Uniform fill#2114Annukir fill#2109I I 1 t (3700 3Sm3 3900 a 4100 4200 4300 4400Energy (eV)FIGURE 3. Heliumlike and hydrogerdikeAr Rydbag series for uniform and annular fill z-pinch plasmas.RESULTSA plot of the heliurrdike and hydrogenlike Rydbag seriesis shown for both a uniform and annular gas puffin Fig. 3.The spectra is obtained by taking a horizontal projection ofthe data on the center strip as in Fig. 2. The uniform fillplasmas which had less mass and were less dense implodeat a faster We@ stagnate on axis with a highereleetmntemperature, and reach a higher ionization balance. Thiswas evident from the data in Fig. 3 showing that theuniform fill gas p@s had a higher ratio of the H-like to He-Iike k Rydberg series.The electron density ne, ion density ni, and iontemperature Ti are inferred from a fit to the He-like ArRydberg series. We performed a two component Gaussianleast-squared fit to the data. One component was assumed tobe due to a constant Doppler line broadening and the otherdue to Stark broadening in which the width of the lines wasassumed to vary as N2 ne2D where N is the principlequantum number of the upper level in the Rydbergtransition From the Doppler width we interpreted the iontemperature to be 36 lceV, but this may also be evidence ofturbulence or mass motion. To infer the electron density wecompared the experimental Stark width from the fit to thatcomputed by the l’OTAL calculation(4). TOTAL is a codein which the Stark broadening of line radiation in a plasmacan be determined from the electric microfiekis produced atthe radiator by ion and electron perturbers. We determinedan electron density of 0.8 x 1021 cm-3 for the annular gaspuff. Assuming this electron density and a plasmaconsisting of 90°A NelO+ and 10°/0Ar16+, the density ofthe plasma is 0.0028 g/cm3.ml Ibdial profiles.’m01L61.il.OZll.4U 2.!Uz1e1 1 I 1 I 1 1a.louse.mu$wus MO @As-ws hid do =exp(u kev(re)12-:M-2s-6-47 .11 I I I 1 [ I 11.6 la w 22 u u u 3.0?Od4iom (-)FIGURE 4. One- and two-dimensional electron temperature maps can be determined from spectra and monochromatic images of theNe free-bound continuum near 2 and 4 keV..,~The 2D electron temperatures Te arc determined from theslope of the hydrogenlike Ne free-bound continuumradiation for these optically thin plasmas. The slope iscomputed by taking the ratio of the ADP and quartz x-myintensities I(E) and I(E+AE), respectively, where E is thephoton energy and using the I(E)/I(E+AE) = exp(AE/kTe)intensity fall off of a Maxwellian electron velocitydistribution. The intensity ratios are corrected for absolutespectrometer efficiency of each crystal, Be-filtertransmission, MCP detector gating response, filmsensitivity, x-ray tmnsmission through the gas column, andthe magnification dHerence for the ADP and qumtz imagingcIYstals. The spectrometer was absolutely calibrated usingAu bremsstrahlung x-rays produced by a ManSon source.We meamued the diffracted x-rays on the detector using asingle photon counting photomultiplier tube (PMT) systemrelative to the direct x-ray flux monitored by a windowlesslithiun-drifted silicon Si(Li) detector. The radial temperatureprofiles were determined by taking mdial projections of theNe free-bound radiation from the ADP crystal data (top stripin Fig. 2) at an x-ray energy of 1.7 keV and from the quartzcrystal at 3.7 keV (middle strip in Fig. 2). Similarly, theaxial temperature profiles were inferrred from axialprojections of the 2D monochromatic Ne free-bound imagesfrom the ADP and quartz imaging cqwta.ls at x-ray energiesof 2.03 keV and 3.73 keV, respectively, as seen on thebottom strip in Fig. 2. The results are shown on Fig. 4.We measured peak radial and axial electron temperatures of1.2 keV for the annular fill plasma and 1.6 keV for theuniform fill plasma.We have compared our results to both 2D localthermodynamic equilibrium (LTE) simulations(2) where thelevel populations are statistically populated and 2D non-LTE calculations where the populations are determined byrate equations. The predicted x-ray pulse widths and totalradiation yields are in reasonable agreement with themeasurements. However, the models also give higherdensities, smaller radii, and lower temperatures at stagnationwhen compared with the experiment. The 2D LTEcalculation predicts a stagnation density of-1 g/cm3 andthe fidl width at half maximum (FWHM) of the pinch to be- microns vs. 2 mm for the experiment with an electrontemperate of 300 eV. The 2D non-LTE model gives animproved stagnation density of-10-2 j#cm3 with a FWMHpinch of 0.5 mm and an electron temperature of 700 eV. Inthese models in which the plasma cools by radiating duringthe implosion the fiml predicted temperatures are too lowto produce the H-like Ar ionization state seen in themeasurement. Tle discreprmcies could be due to 3D effectssuch as additional angular momentum breaking theazimuthal symmetry and turbulence in the equation of statewhich both would prevent the plasma from reaching thehigh densities at stagnationIn conclusion we have performed the first high resolutiontime-resolved measurements of the plasma conditions of aZ-pinch accelerator at stagmtion. 2D electron temperatureprofiles, electron densities, ion temperatures, and iondensities we~ inferied to compare with 2D radiation MHDmodels. We find the simulations predict plasmas that aretoo dense, tightly pinched, and cool at stagmtion. Possible3D effects and adding turbulence may explain thesedisc~pancies.ACKNOWLEDGEMENTSWe wish to thank A. Toor and M. E&M for their supportof the experiment and the SATURN PRS crew for theirteehnical assistance. This work was performed under theauspices of the U. S. Department of Energy by LawrenceLivermore National Laborato~ and Sandial NationalLaboratories under contracts W-7405 -ENG-48 and DE-AC04-94AL85000.REFERENCES1. PereimjN. R. and Davis J.,1 AppL Phys 64, p. RI (1988).2. Hamma, J. H. et al, Phys. Plasmas 3, p. 2063 (1996).3. BkwmquiX D. D. et al., Proceedings of the 6th Znstitu@ ofElectrical and Electronics Engineers Pulsed PowerConference, Arlingtow VA, 1987,p. 310.4. Calis&A. etal., Phys. Rev. A 42, p. 5433 (1990).Technical Information Department  • Lawrence Livermore National LaboratoryUniversity of California • Livermore, California  94551

One- and two-dimensional density and temperature measurements of an argon-neon Z-pinch plasma at stagnation

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One- and two-dimensional density and temperature measurements of an argon-neon Z-pinch plasma at stagnation

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