Physical studies of fast ignition in China

He, X. T.; Cai, Hong-bo; Wu, S. Z.; Cao, Liangcai; Zhong, Hua; He, Mingqing; Chen, Mo; Wu, J. F.; Zhou, C. T.; Zhou, Weimin; Shan, Lianqiang; Wang, Weiwu; Zhang, Feng; Bi, Bi; Zhao, Zili; Gu, Yuqiu; Zhang, Baohan; Wang, Wei; Fang, Zhiheng; Lei, Anle; Wang, Chen; Pei, Wenbing; Fu, Sizu

doi:10.1088/0741-3335/57/6/064003

Cited by 10 publications

(2 citation statements)

References 76 publications

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“…Minimizing the non-implosion neutron yield remains a challenge for the full-scale direct-drive fast ignition. In order to reduce the hot electron preheating, indirect-drive FI experiments have been performed on the SG-II upgrade and the SG-III prototype laser facilities [4,5]. In contrast to the direct-drive scheme, the nanosecond laser beams first strike the inside wall of a high-Z hohlraum to produce an x-ray radiation bath, which then ablates and implodes the fuel capsule.…”

Section: Anomalous Neutron Yield In Indirect-drive Inertial-confineme...mentioning

confidence: 99%

Anomalous neutron yield in indirect-drive inertial-confinement-fusion due to the formation of collisionless shocks in the corona

Zhang

Cai

Shan³

et al. 2017

Nucl. Fusion

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Observations of anomalous neutron yield in the indirect-drive inertial confinement fusion implosion experiments conducted at SG-III prototype and SG-II upgrade laser facilities are interpreted. The anomalous mechanism results in a neutron yield which is 100-times higher than that predicted by 1D radiation-hydrodynamic simulations. 2D radiation-hydrodynamic simulations show that the supersonic, radially directed gold (Au) plasma jets arising from the laser-hohlraum interactions can collide with the carbon-deuterium (CD) corona plasma of the compressed pellet. It is found that in the interaction front of the high-Z jet with the low-Z corona, with low density ∼ − 10 cm 20 3 and high temperature ∼keV, kinetic effects become important. Particle-in-cell simulations indicate that an electrostatic shock wave can be driven when the high-temperature Au jet expands into the low-temperature CD corona. Deuterium ions with an amount of ∼10 15 can be accelerated to ∼25 keV by the collisionless shock wave, thus causing efficient neutron productions though the beam-target method by stopping these energetic ions in the corona. The evaluated neutron yield is consistent with the experiments conducted at SG laser facilities.

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Section: Anomalous Neutron Yield In Indirect-drive Inertial-confineme...mentioning

confidence: 99%

Anomalous neutron yield in indirect-drive inertial-confinement-fusion due to the formation of collisionless shocks in the corona

Zhang

Cai

Shan³

et al. 2017

Nucl. Fusion

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“…Ion acceleration via laser-plasma interaction [1] has attracted extensive attention with the rapid development of ultrashort, ultraintense laser technology in recent decades. For its unique characteristics such as high energy and small divergence [2], it has potential scientific applications in a variety of aspects such as inertial confinement fusion (ICF) [3][4][5][6], tumor therapy [7,8], and proton imaging [9,10]. Several mechanisms for laserdriven ion acceleration have been proposed and observed experimentally over the past decades, including target normal sheath acceleration (TNSA) [11,12], radiation pressure acceleration (RPA) [13][14][15], break-out afterburner (BOA) [16,17], magnetic vortex acceleration (MVA) [18,19], and collisionless shock acceleration (CSA) [20][21][22].…”

Section: Introductionmentioning

confidence: 99%

Enhanced Proton Acceleration by Laser-Driven Collisionless Shock in the Near-Critical Density Target Embedding with Solid Nanolayers

et al. 2021

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Effects of solid nanolayers embedded in a near-critical density plasma on the laser-driven collisionless shock acceleration are investigated by using two-dimensional particle-in-cell simulations. Due to the interaction of nanolayers and the incident laser, an additional number of hot electrons are generated and an inhomogeneous magnetic field is induced. As a result, the collisionless shock is reinforced within the nanolayer gaps compared to the target without the structured nanolayers. When the laser intensity is 9.8 × 10 19 W / cm 2 , the amplitude of the electrostatic field is increased by 30% and the shock velocity is increased from 0.079c to 0.091c, leading to an enhancement of the peak energy and the cutoff energy of accelerated protons, from 6.9 MeV to 9.1 MeV and 12.2 MeV to 20.0 MeV, respectively. Furthermore, the effects of the width of the nanolayer gaps are studied, by adjusting the gap width of nanolayers, and optimal nanolayer setups for collisionless shock acceleration can be acquired.

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