VOLUME IGNITION OF INERTIAL CONFINEMENT FUSION OF DEUTERIUM HELIUM(3) AND HYDROGEN BORON(11) CLEAN FUSION FUEL

被引：14

作者：

PIERUSCHKA, P

CICCHITELLI, L

KHODABAKHSH, R

KUHN, E

MILEY, GH

HORA, H

机构：

[1] UNIV NEW S WALES,DEPT THEORET PHYS,KENSINGTON,NSW 2033,AUSTRALIA

[2] UNIV ILLINOIS,FUS STUDIES LAB,URBANA,IL 61801

来源：

LASER AND PARTICLE BEAMS | 1992年 / 10卷 / 01期

关键词：

D O I：

10.1017/S0263034600004274

中图分类号：

O59 [应用物理学];

学科分类号：

摘要：

Since DT laser fusion with 10-MJ laser pulses for 1000-MJ output now offers the physics solution for an economical fusion energy reactor, the conditions are evaluated assuming that controlled ICF reactions will become possible in the future using clean nuclear fusion fuel such as deuterium-helium(3) or hydrogen-boron(11). Using the transparent physics mechanisms of volume ignition of the fuel capsules, we show that the volume ignition for strong reduction of the optimum initial temperature can be reached for both types of fuels if a compression about 100 times higher than those in present-day laser compression experiments is attained in the future. Helium(3) laser-pulse energies are then in the same range as for DT, but ten times higher energies will be required for hydrogen-boron(11).

引用

页码：145 / 154

页数：10

共 50 条

[31] Gain analysis of proton-lithium pellets at inertial confinement fusion with volume ignition
Razavipour, S. S.
Malekynia, B.
INDIAN JOURNAL OF PHYSICS, 2013, 87 (11) : 1109 - 1112
[32] Critical value of volume ignition and condition of nonequilibriem burning of DT in inertial confinement fusion
Zhao Ying-Kui
Ouyang Bi-Yao
Wen Wu
Wang Min
ACTA PHYSICA SINICA, 2015, 64 (04)
[33] Kinetic process analysis of volume thermonuclear ignition in high gain inertial confinement fusion
Li, Yunsheng
Gao, Yaoming
He, Xiantu
Yu, Min
Applied Mathematics and Mechanics (English Edition), 1995, 16 (10): : 325 - 333
[34] Inertial confinement fusion ignition achieved at the National Ignition Facility - an editorial
Danson, C. N.
Gizzi, L. A.
HIGH POWER LASER SCIENCE AND ENGINEERING, 2023, 11
[35] Inertial confinement fusion ignition achieved at the National Ignition Facility–an editorial
C.N.Danson
L.A.Gizzi
High Power Laser Science and Engineering, 2023, 11 (03) : 77 - 79
[36] Sensitivity of inertial confinement fusion hot spot properties to the deuterium-tritium fuel adiabat
Melvin, J.
Lim, H.
Rana, V.
Cheng, B.
Glimm, J.
Sharp, D. H.
Wilson, D. C.
PHYSICS OF PLASMAS, 2015, 22 (02)
[37] Ignition conditions for inertial confinement fusion targets with a nuclear spin-polarized DT fuel
Temporal, M.
Brandon, V.
Canaud, B.
Didelez, J. P.
Fedosejevs, R.
Ramis, R.
NUCLEAR FUSION, 2012, 52 (10)
[38] Neutron imaging of the deuterium-tritium tamping gas volume in an inertial confinement fusion hohlraum
Izumi, N.
Higginson, D. P.
Rosen, M. D.
Riedel, W. M.
Haines, B. M.
Fittinghoff, D. N.
Volegov, P.
Youmans, A. E.
Kemp, A.
Chapman, T.
Hardy, C.
Gjemso, J.
Waltz, C.
Rogers, S. M.
Woodworth, B. N.
Sarginson, T.
Cheung, R.
Masters, N.
Sandoval, R.
Cunningham, T.
Ramirez, R.
Holder, J. P.
Reynolds, R. L.
Holunga, D. M.
Briggs, T. M.
Vonhof, S.
Roskopf, N. T.
Schlossberg, D.
Moore, A. S.
Kerr, S.
Hahn, K. D.
Reichelt, B. L.
Mackinnon, A. J.
Moody, J. D.
Ross, J. S.
Hinkel, D.
REVIEW OF SCIENTIFIC INSTRUMENTS, 2024, 95 (10):
[39] Progress in the shock-ignition inertial confinement fusion concept
Theobald, W.
Casner, A.
Nora, R.
Ribeyre, X.
Lafon, M.
Anderson, K. S.
Betti, R.
Craxton, R. S.
Delettrez, J. A.
Frenje, J. A.
Glebov, V. Yu.
Gotchev, O. V.
Hohenberger, M.
Hu, S. X.
Marshall, F. J.
McCrory, R. L.
Meyerhofer, D. D.
Perkins, L. J.
Sangster, T. C.
Schurtz, G.
Seka, W.
Smalyuk, V. A.
Stoeckl, C.
Yaakobi, B.
IFSA 2011 - SEVENTH INTERNATIONAL CONFERENCE ON INERTIAL FUSION SCIENCES AND APPLICATIONS, 2013, 59
[40] Advances in inertial confinement fusion at the National Ignition Facility (NIF)
Moses, Edward I.
FUSION ENGINEERING AND DESIGN, 2010, 85 (7-9) : 983 - 986

← 1 2 3 4 5 →