| Autor: |
Yongsheng Li, Jianfa Gu, Changshu Wu, Peng Song, Zhensheng Dai, Shuanggui Li, Xin Li, Dongguo Kang, Peijun Gu, Wudi Zheng, Shiyang Zou, Yongkun Ding, Ke Lan, Wenhua Ye, Weiyan Zhang |
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| Zdroj: |
Physics of Plasmas; 2016, Vol. 23 Issue 7, p1-10, 10p, 1 Diagram, 2 Charts, 10 Graphs |
| Abstrakt: |
Low-mode asymmetries in the laser-indirect-drive inertial confinement fusion implosion experiments conducted on the National Ignition Facility [G. H. Miller et al, Nucl. Fusion 44, S228 (2004)] are deemed the main obstacles hindering further improvement of the nuclear performance of deuterium-tritium-layered capsules. The dominant seeds of these asymmetries include the P2 and P4 asymmetries of x-ray drives and P2 asymmetry introduced by the supporting "tent." Here, we explore the effects of another possible seed that can lead to low-mode asymmetric implosions, i.e., the M-band flux asymmetry (MFA) in laser-driven cylindrical gold Hohlraums. It is shown that the M-band flux facilitates the ablation and acceleration of the shell, and that positive P2 MFAs can result in negative P2 asymmetries of hot spots and positive P2 asymmetries of shell's qR. An oblate or toroidal hot spot, depending on the P2 amplitude of MFA, forms at stagnation. The energy loss of such a hot spot via electron thermal conduction is seriously aggravated not only due to the enlarged hot spot surface but also due to the vortices that develop and help transferring thermal energy from the hotter center to the colder margin of such a hot spot. The cliffs of nuclear performance for the two methodologies of applying MFA (i.e., symmetric flux in the presence of MFA and MFA added for symmetric soft x-ray flux) are obtained locating at 9.5% and 5.0% of P2/P0 amplitudes, respectively. [ABSTRACT FROM AUTHOR] |
| Databáze: |
Complementary Index |
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