Experimental study of the structure of the plasma-current sheath on the PF-1000 facility

Krauz, V. I.; Mitrofanov, K. N.; Scholz, M.; Paduch, M.; Karpinski, L.; Zielinska, E.; Kubeš, P.

doi:10.1088/0741-3335/54/2/025010

Cited by 44 publications

(43 citation statements)

References 34 publications

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“…With neon filling, we recorded increase of their length with an average velocity of (2.5 6 0.5) Â 10 5 m/s. If we taken into account (i) the increase of the current and associated magnetic field in internal structures during the formation of plasmoids 24,25 and (ii) the current being carried through these short filaments, we can speculate that they are the traces of some dense points of filaments, (nodules 1 ) which marked the transport of certain filaments from the external current sheath through the cold layer to the internal dense plasmoids to increase the internal closed currents. They should not be the traces of the acceleration of fast ions.…”

Section: Summary and Discussionmentioning

confidence: 99%

Filamentary structure of plasma produced by compression of puffing deuterium by deuterium or neon plasma sheath on plasma-focus discharge

et al. 2014

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The present experiments were performed on the PF-1000 plasma focus device at a current of 2 MA with the deuterium injected from the gas-puff placed in the axis of the anode face. The XUV frames showed, in contrast with the interferograms, the fine structure: filaments and spots up to 1 mm diameter. In the deuterium filling, the short filaments are registered mainly in the region of the internal plasmoidal structures and their number correlates with the intensity of neutron production. The longer filamentary structure was recorded close to the anode after the constriction decay. The long curve-like filaments with spots were registered in the big bubble formed after the pinch phase in the head of the umbrella shape of the plasma sheath. Filaments can indicate the filamentary structure of the current in the pinch. Together with the filaments, small compact balls a few mm in diameter were registered by both interferometry and XUV frame pictures. They emerge out of the dense column and their life-time can be greater than hundreds of ns. V C 2014 AIP Publishing LLC.

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Section: Summary and Discussionmentioning

confidence: 99%

Filamentary structure of plasma produced by compression of puffing deuterium by deuterium or neon plasma sheath on plasma-focus discharge

et al. 2014

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“…Measurements of the current distribution [4][5][6][7] showed that a fraction of the discharge current could form closed loops near the insulator and not be involved in the process of plasma compression. However, it was also shown that, in optimized PF operating modes with a neutron yield as high as 10 10 -10 11 neutrons/shot, the efficiency of current transportation toward the facility axis can reach 100% [8,9]. It should also be noted that inefficient transportation of the discharge current toward the facility axis can be caused, in particular, by the azi-PLASMA DYNAMICS muthal inhomogeneity of the PCS, which has a filamentary structure throughout all discharge stages [10][11][12].…”

Section: Introductionmentioning

confidence: 99%

Study of the interrelation between the electrotechnical parameters of the plasma focus discharge circuit and the plasma compression dynamics on the PF-3 and PF-1000 facilities

et al. 2015

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The main stages of the plasma current sheath (PCS) dynamics on two plasma focus (PF) facilities with different geometries of the electrode system, PF-3 (Filippov type) and PF-1000 (Mather type), were studied by analyzing the results of the current and voltage measurements. Some dynamic characteristics, such as the PCS velocity in the acceleration phase in the Mather-type facility (PF-1000), the moment at which the PCS reaches the anode end, and the plasma velocity in the radial stage of plasma compression in the PF-3 Filippov-type facility, were determined from the time dependence of the inductance of the discharge circuit with a dynamic plasma load. The energy characteristics of the discharge circuit of the compressing PCS were studied for different working gases (deuterium, argon, and neon) at initial pressures of 1.5-3 Torr in discharges with energies of 0.3-0.6 MJ. In experiments with deuterium, correlation between the neutron yield and the electromagnetic energy deposited directly in the compressed PCS was investigated.

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“…The higher stability of the pinch column at the applied magnet protects both the production of this first neutron pulse and the penetration of the internal discharge current into the dense column [16], [24]. This penetration is realized 200-300 ns after the pinch phase characterized by the peak of the SXRs, as we observe in EI and EIII of Fig.…”

Section: Conclusion and Discussionmentioning

confidence: 52%

“…Fast electrons and ions with an energy of hundred kiloelectronvolts were produced in correlation with the formation and disintegration of these structures. The signals of the magnetic probes confirmed the existence of azimuthal and axial components of the magnetic field in the pinch [16], [17]. The evolution of the spontaneously generated axial magnetic field in the dense toroidal, helical, and plasmoidal structures was described in [18].…”

Section: Puffing Deuterium Compressed By a Neon Plasmamentioning

confidence: 56%

“…It is known that the first HXR and neutron pulses correlate with the penetration of the current into the dense pinch and formation of the plasmoid [16]. The higher stability of the pinch column at the applied magnet protects both the production of this first neutron pulse and the penetration of the internal discharge current into the dense column [16], [24].…”

Section: Conclusion and Discussionmentioning

confidence: 99%

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Puffing Deuterium Compressed by a Neon Plasma Sheath at the Initial Poloidal Magnetic Field in Plasma Focus Discharge

Kubeš

Paduch

Cikhardt

et al. 2015

IEEE Trans. Plasma Sci.

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This paper presents the results of the experimental study of the influence of the applied poloidal magnetic field on the transformation of the plasma column formed by the compression of (10 ± 3)-µg/cm deuterium injected by the gas-puff nozzle in front of the anode axis by the neon plasma sheath of (50 ± 10) µg/cm at a current of 2 MA. The permanent magnet with an initial induction of 20-40 mT placed inside the anode: 1) increased the diameter of the pinch and of the stagnation; 2) depressed the evolution of instabilities and formation of the dense structures in the column; 3) delayed the dip of the current derivative in time (and start of the hard X-ray and neutron emission) 200-300 ns after the first peak of the soft X-ray emission (and the pinch with a minimal diameter near the anode); and 4) decreased the total neutron yield to 10-20%. These results were interpreted in terms of the increase in the repulsive pressure of the compressed poloidal magnetic field, which increases the stabilizing helicity of the discharge current. The transformations are independent of the polarity of the magnet.Index Terms-Dense plasma focus, fusion neutron sources, interferometry diagnostics, stabilization of pinched plasma.

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Experimental study of the structure of the plasma-current sheath on the PF-1000 facility

Cited by 44 publications

References 34 publications

Filamentary structure of plasma produced by compression of puffing deuterium by deuterium or neon plasma sheath on plasma-focus discharge

Filamentary structure of plasma produced by compression of puffing deuterium by deuterium or neon plasma sheath on plasma-focus discharge

Study of the interrelation between the electrotechnical parameters of the plasma focus discharge circuit and the plasma compression dynamics on the PF-3 and PF-1000 facilities

Puffing Deuterium Compressed by a Neon Plasma Sheath at the Initial Poloidal Magnetic Field in Plasma Focus Discharge

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