Z-pinch plasma neutron sources

Velikovich, A. L.; Clark, R. W.; Davis, J.; Chong, Y. K.; Deeney, C.; Coverdale, C. A.; Ruiz, C. L.; Cooper, G. W.; Nelson, A. J.; Franklin, J.; Rudakov, L. I.

doi:10.1063/1.2435322

Cited by 95 publications

(66 citation statements)

References 47 publications

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“…This is consistent with expectations since the implosion velocity (70 km/s) is too low to generate such high temperatures in a non-magnetized, non-preheated target. The isotropic, near-Gaussian DD NTOF spectra, DD yield isotropy, high ion and electron temperatures (with T i ≈ T e ), and the large secondary DT yield provide evidence for a thermonuclear origin of the yield rather than beam-target reactions, which have been suggested as a significant source of yield in other magnetically-driven implosions [32][33][34]. The range of measured DD yields (5e11-2e12) is encompassed by the 2e11-6e13 thermonuclear yield range estimated based on the 0.2-0.6 g/cm 3 fuel density (from x-ray yield), 2-3.1 keV temperature (from NTOF and x-ray spectra), 0.02-0.05 mm 3 volume (from x-ray imaging), and 1-2 ns duration (from x-ray emission history).…”

mentioning

confidence: 99%

Experimental Demonstration of Fusion-Relevant Conditions in Magnetized Liner Inertial Fusion

Gómez¹,

Slutz²,

Sefkow³

et al. 2014

Phys. Rev. Lett.

369

186

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confidence: 99%

Experimental Demonstration of Fusion-Relevant Conditions in Magnetized Liner Inertial Fusion

Gómez¹,

Slutz²,

Sefkow³

et al. 2014

Phys. Rev. Lett.

369

186

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“…The relaxation time of Coulomb interaction for deuteron-deuteron collisions given by formula τ ii = 2.3x10 13 (T(eV) 3/2 /n.lnΛ) and the relaxation time of Coulomb interaction for deuteron-deuteron collisions has the value of 10-40 ns (for n i = 10 25 and E d =(1-2) keV), while the time of equilibrium between electrons and ions in these conditions given by Coulomb interaction τ ei = τ ii (m/M) 1/2 (Ei/Te) 3/2 is effective for electron temperature below 0.1 keV [13]. Fast ions can produce an additional heating of deuterons and electrons [14,15] of the target.…”

Section: Discussionmentioning

confidence: 99%

Study of D-D Reaction at the Plasma Focus Device

Kubeš¹,

Kravárik²,

Klír³

et al. 2008

AIP Conference Proceedings

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Abstract. The plasma focus device PF-1000 at IPPLM Warsaw with neutron yields of 10 9 -10 11 neutrons per shot is convenient for the determination of the axial neutron energy distribution in the fusion D-D reaction due to the horizontal position of a discharge axis and the distance of scintillation detectors up to 85 m from the neutron source in both axial (downstream and upstream) directions. In this paper the determination of the axial energy component of the fast deuterons producing neutrons is presented for the shot with a relative small neutron yield and nearly isotropic neutron energy distribution and the total energy of fast deuterons producing neutrons is estimated. We calculated, if the dense structure with the length of 2 cm and the density of 2x10 25 m -3 could be the source of neutrons. We estimated the upper limit of energy of deuterons producing neutrons as 10-20 keV and their total number as 10 18 . The deuterons with energies below 10-20 keV can't produce high number of neutrons due to the small cross-section of D-D reaction but they can be principally confined by magnetic field. We discuss the influence of magnetic field on the motion of deuterons.

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“…Neutron yields in dense Z-pinch experiments and in numerical simulations are generally observed as scaling with the current to the fourth power [1][2][3]. A deviation from a single I 4 scaling exists for currents around a few mega-amps [4].…”

mentioning

confidence: 99%