Enhanced energy coupling for indirect-drive fast-ignition fusion targets
Autor: | W. W. Wang, B. H. Zhang, H. Zhang, L. H. Cao, Shaoping Zhu, G. L. Ren, L. Yang, S. Z. Wu, Xian-Tu He, L. Wei, Z. H. Yang, J. F. Gu, M. Q. He, S. Y. Zou, F. Lu, Jian Li, W. D. Zheng, B. Zhang, H. J. Liu, K. Du, H. Xu, L. F. Cao, W. M. Zhou, Y. M. Yang, Hong-bo Cai, Q. Tang, F. Zhang, J. F. Wu, Zhao-Shen Li, Z. Q. Yuan, B. Cui, L. Q. Shan, W. Qi, J. B. Chen, C. T. Zhou, Y. K. Ding, H. S. Zhang, B. Bi, M. H. Yu, Z. S. Dai, F. J. Ge, C. Tian, W. Y. Zhang, D. X. Liu, H. B. Du, Y. Q. Gu, W. S. Zhang |
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Rok vydání: | 2020 |
Předmět: |
Physics
Resistive touchscreen General Physics and Astronomy Plasma 01 natural sciences 010305 fluids & plasmas law.invention Magnetic field Computational physics Ignition system Physics::Plasma Physics Hohlraum law 0103 physical sciences Relativistic electron beam 010306 general physics National Ignition Facility Inertial confinement fusion |
Zdroj: | Nature Physics. 16:810-814 |
ISSN: | 1745-2481 1745-2473 |
DOI: | 10.1038/s41567-020-0878-9 |
Popis: | One of the most promising approaches to reach a high gain in inertial confinement fusion is the fast ignition scheme. In this scheme, a relativistic electron beam is generated; this passes through the imploded plasma and deposits parts of its energy in the core. However, the large angular spread of the relativistic electron beam and the poorly controlled compression of the target affect realization of the fast ignition technique. Here, we demonstrate that indirectly driven (that is, driven by X-rays generated inside a gold hohlraum) implosions with a ‘high-foot’ and a short-coast time of less than 200 ps allow us to tightly compress the shell. Furthermore, we show the ability to optimize the symmetry of the imploding shell by changing the hohlraum length, successfully tuning a suitable tube-shaped shell to compensate for the large angular spread of the relativistic electron beam and to enhance the electron-to-core coupling efficiency via resistive magnetic fields. Benefiting from those experimental techniques, a significant enhancement in neutron yield was achieved in our indirectly driven fast ignition experiments. These results pave the way towards high-coupling fast ignition experiments with indirectly driven targets similar to those at the National Ignition Facility. Experiments realizing the indirect-drive fast ignition scheme for inertial confinement fusion are reported. Enabled by a tightly compressed target, an increase of neutron yield is observed. |
Databáze: | OpenAIRE |
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