Quasi-spherical superfast Z-pinch implosion for pellet irradiation

• Autorzy: Smirnov V. P. , Grabovskii E. V. , Zakharov S. V.
• Konferencja: International Conference on Research and Applications of Plasmas, Plasma-2011, 12-16 September 2011, Warsaw, Poland
• Języki publikacji: EN

Abstrakty

EN

New simulation results of the quasi-spherical implosion induced by a 40 MA current pulse are discussed. Results on a quasi-spherical wire array production and some experimental observations of an implosion are presented.

Słowa kluczowe

EN

Z-pinch; Z-pinch implosion

• Wydawca: Institute of Nuclear Chemistry and Technology
• Czasopismo: Nukleonika
• Rocznik: 2012
• Tom: Vol. 57, No. 2
• Strony: 215--219
• Opis fizyczny: Bibliogr. 13 poz., rys.

Twórcy

autor

Smirnov V. P.

autor

Grabovskii E. V.

autor

Zakharov S. V.

• Joint Institute for High Temperatures, Russian Academy of Sciences (JIHT RAS), 13/2 Izhorskaya Str., 125412, Moscow, Russia, Tel.: +7 495 485 9333, Fax: +7 495 485 7990,

Bibliografia

• 1. Benattar R, Zakharov SV, Nikiforov AF et al. (1999) Influence of magnetohydrodynamic Rayleigh-Taylor instability on radiation of imploded heavy ion plasmas. Phys Plasmas 6:175–187
• 2. Kosarev VI, Lobanov AI, Chukbar KV, Shestakov YI (1989) About possibility of organization of three-dimensional implosion of inhomogeneous liner. VANT, Therm Sint 3:46–50
• 3. Matzen MK (1997) Z pinches as intense X-ray sources for high-energy density physics application. Phys Plasmas 4:1519–1527
• 4. Mokhov VN, Chernyshev VK, Yakubov VB et al. (1979) On a possibility to solve controlled thermonuclear fusion problem on the basis of magnetodynamic energy cumulation. Sov Phys Dokl 24:557–563
• 5. Nash TJ, McDaniel DH, Leeper RJ et al. (2005) Design, simulation, and application of quasi-spherical 100 ns z-pinch implosions driven by tens of mega-amperes. Phys Plasmas 12:052705-1-9
• 6. Nikiforov AF, Novikov VG, Uvarov VB (2005) Quantum-statistic models of hot dense matter and methods for computation of opacity and equation of state Birkhauser
• 7. Novikov VG, Zakharov SV (2003) Modeling of non-equilibrium radiating tungsten liners. JQSRT 81:339–354
• 8. Sanford TWL, Lemke RW, Mock RC et al. (2002) Dynamics and characteristics of a 215-eV dynamic-hohlraum X-ray source on Z. Phys Plasmas 9:3573–3594
• 9. Smirnov VP (1991) Fast liners for inertial fusion. Plasma Phys Control Fusion 33:1697–1714
• 10. Smirnov VP, Zakharov SV, Grabovskii EV (2005) Increase in radiation intensity in a quasi-spherical “Double Liner”/“Dynamic Hohlraum” system. JETP Lett 81:442–447
• 11. Zakharov SV, Novikov VG, Stepanov AE et al. (1994) ZETA Code. Report 11. Keldysh Institute of Applied Mathematics, Moscow
• 12. Zakharov SV, Smirnov VP (2005) Augmentation of radiation intensity in quasi-spherical double Liner/Dynamic Hohlraum. In: Chittenden J (ed) AIP Conf Proc no. 808. Oxford, UK, pp 358–362
• 13.Zakharov SV, Smirnov VP, Krukovskiy AY et al. (1988) Collision of current driven cylindrical liners. Preprint 4587/6. Institute of Atomic Energy, Moscow