Supplemental heating of conventional Inertial Confinement Fusion

被引：0

作者：

Thomas, B. R. ^{[1
]}

Hughes, S. J. ^{[1
]}

Garbett, W. J. ^{[1
]}

Sircombe, N. J. ^{[1
]}

机构：

[1] AWE Plc, Reading RG7 4PR, Berks, England

来源：

8TH INTERNATIONAL CONFERENCE ON INERTIAL FUSION SCIENCES AND APPLICATIONS (IFSA 2013) | 2016年 / 688卷

关键词：

IGNITION; PHYSICS;

D O I：

10.1088/1742-6596/688/1/012034

中图分类号：

P1 [天文学];

学科分类号：

0704 ;

摘要：

We report a new ICF scheme whereby a capsule is imploded to near ignition conditions and subsequently flooded with hot electrons generated from a short-pulse laser plasma interaction so as to heat the whole assembly by a few hundred eV. The cold dense shell pressure is increased by a larger factor than that of the hot spot at the capsule core, so that further heating and compression of the hot spot occurs. We suggest it may be possible to drive the capsule to ignition by the pressure augmentation supplied by this extra deposition of energy.

引用

页数：4

共 50 条

[1] A comprehensive alpha-heating model for inertial confinement fusion
Christopherson, A. R.
Betti, R.
Bose, A.
Howard, J.
Woo, K. M.
Campbell, E. M.
Sanz, J.
Spears, B. K.
PHYSICS OF PLASMAS, 2018, 25 (01)
[2] Instabilities and Mixing in Inertial Confinement Fusion
Zhou, Ye
Sadler, James D.
Hurricane, Omar A.
ANNUAL REVIEW OF FLUID MECHANICS, 2025, 57 : 197 - 225
[3] Inertial confinement fusion: a defence context
Randewich, Andrew
Lock, Rob
Garbett, Warren
Bethencourt-Smith, Dominic
PHILOSOPHICAL TRANSACTIONS OF THE ROYAL SOCIETY A-MATHEMATICAL PHYSICAL AND ENGINEERING SCIENCES, 2020, 378 (2184):
[4] Diagnosing inertial confinement fusion ignition
Moore, A. S.
Divol, L.
Bachmann, B.
Bionta, R.
Bradley, D.
Casey, D. T.
Celliers, P.
Chen, H.
Do, A.
Dewald, E.
Eckart, M.
Fittinghoff, D.
Frenje, J.
Gatu-Johnson, M.
Geppert-Kleinrath, H.
Geppert-Kleinrath, V.
Grim, G.
Hahn, K.
Hohenberger, M.
Holder, J.
Hurricane, O.
Izumi, N.
Kerr, S.
Khan, S. F.
Kilkenny, J. D.
Kim, Y.
Kozioziemski, B.
Lemos, N.
MacPhee, A. G.
Michel, P.
Millot, M.
Meaney, K. D.
Nagel, S.
Pak, A.
Ralph, J. E.
Ross, J. S.
Rubery, M. S.
Schlossberg, D. J.
Smalyuk, V.
Swadling, G.
Tommasini, R.
Trosseille, C.
Zylstra, A. B.
Mackinnon, A.
Moody, J. D.
Landen, O. L.
Town, R.
NUCLEAR FUSION, 2024, 64 (10)
[5] Motivation and fabrication methods for inertial confinement fusion and inertial fusion energy targets
Borisenko, NG
Akunets, AA
Bushuev, VS
Dorogotovtsev, VM
Merkuliev, YA
LASER AND PARTICLE BEAMS, 2003, 21 (04) : 505 - 509
[6] Neutron imaging of inertial confinement fusion implosions
Fittinghoff, D. N.
Birge, N.
Geppert-Kleinrath, V.
REVIEW OF SCIENTIFIC INSTRUMENTS, 2023, 94 (02)
[7] Modelling of Silicon in inertial confinement fusion conditions
Hill, E. G.
Rose, S. J.
HIGH ENERGY DENSITY PHYSICS, 2012, 8 (04) : 307 - 312
[8] First Inertial Confinement Fusion Implosion Experiment
Lan, Ke
Dong, Yunsong
Wu, Junfeng
Li, Zhichao
Chen, Yaohua
Cao, Hui
Hao, Liang
Li, Shu
Ren, Guoli
Jiang, Wei
Yin, Chuansheng
Sun, Chuankui
Chen, Zhongjing
Huang, Tianxuan
Xie, Xufei
Li, Sanwei
Miao, Wenyong
Hu, Xin
Tang, Qi
Song, Zifeng
Chen, Jiabin
Xiao, Yunqing
Che, Xingsen
Deng, Bo
Wang, Qiangqiang
Deng, Keli
Cao, Zhurong
Peng, Xiaoshi
Liu, Xiangming
He, Xiaoan
Yan, Ji
Pu, Yudong
Tu, Shaoyong
Yuan, Yongteng
Yu, Bo
Wang, Feng
Yang, Jiamin
Jiang, Shaoen
Gao, Lin
Xie, Jun
Zhang, Wei
Liu, Yiyang
Zhang, Zhanwen
Zhang, Haijun
He, Zhibing
Du, Kai
Wang, Liquan
Chen, Xu
Zhou, Wei
Huang, Xiaoxia
PHYSICAL REVIEW LETTERS, 2021, 127 (24)
[9] Development of Compton radiography of inertial confinement fusion implosions
Tommasini, R.
Hatchett, S. P.
Hey, D. S.
Iglesias, C.
Izumi, N.
Koch, J. A.
Landen, O. L.
MacKinnon, A. J.
Sorce, C.
Delettrez, J. A.
Glebov, V. Yu.
Sangster, T. C.
Stoeckl, C.
PHYSICS OF PLASMAS, 2011, 18 (05)
[10] Inertial Confinement Fusion: Bottling the Sun by Laser Beams
Gupta, Naveen
NONLINEAR OPTICS QUANTUM OPTICS-CONCEPTS IN MODERN OPTICS, 2023, 58 (3-4): : 249 - 281

← 1 2 3 4 5 →