Simulations of compression and thermonuclear burn of a radiation-driven inertial-fusion target

N. A. Tahir; D. H.H. Hoffmann; J. A. Maruhn; C. Deutsch

doi:10.1007/BF02780596

Simulations of compression and thermonuclear burn of a radiation-driven inertial-fusion target

N. A. Tahir
, D. H.H. Hoffmann
, J. A. Maruhn
, C. Deutsch

GSI Helmholtz Centre for Heavy Ion Research
Goethe University Frankfurt
Universite Paris-Sud

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

One-dimensional numerical simulations of compression and burn of a reactor-size inertial fusion target imploded by a homogeneous thermal radiation field are presented. This target consists of a multi-layered fusion capsule that is surrounded by a solid gold casing whose radius is twice the outer capsule radius. The target absorbs about 5.4 MJ input radiation energy, about 55% of which is absorbed by the capsule while the rest is lost into the casing. The implosion yields an output thermonuclear energy of 770 MJ so that the capsule gain is of the order of 250 and the target gain is about 140. Larger values of the casing to capsule radii ratio, probably required for achieving a symmetric implosion, would lead to smaller gains, but would not change substantially the qualitative physics aspects discussed in this paper.

Original language	English
Pages (from-to)	1919-1924
Number of pages	6
Journal	Il Nuovo Cimento A
Volume	106
Issue number	12
DOIs	https://doi.org/10.1007/BF02780596
State	Published - Dec 1993
Externally published	Yes

Keywords

Fusion reactors and thermonuclear power studies

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10.1007/BF02780596

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title = "Simulations of compression and thermonuclear burn of a radiation-driven inertial-fusion target",

abstract = "One-dimensional numerical simulations of compression and burn of a reactor-size inertial fusion target imploded by a homogeneous thermal radiation field are presented. This target consists of a multi-layered fusion capsule that is surrounded by a solid gold casing whose radius is twice the outer capsule radius. The target absorbs about 5.4 MJ input radiation energy, about 55\% of which is absorbed by the capsule while the rest is lost into the casing. The implosion yields an output thermonuclear energy of 770 MJ so that the capsule gain is of the order of 250 and the target gain is about 140. Larger values of the casing to capsule radii ratio, probably required for achieving a symmetric implosion, would lead to smaller gains, but would not change substantially the qualitative physics aspects discussed in this paper.",

keywords = "Fusion reactors and thermonuclear power studies",

author = "Tahir, \{N. A.\} and Hoffmann, \{D. H.H.\} and Maruhn, \{J. A.\} and C. Deutsch",

year = "1993",

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doi = "10.1007/BF02780596",

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T1 - Simulations of compression and thermonuclear burn of a radiation-driven inertial-fusion target

AU - Tahir, N. A.

AU - Hoffmann, D. H.H.

AU - Maruhn, J. A.

AU - Deutsch, C.

PY - 1993/12

Y1 - 1993/12

N2 - One-dimensional numerical simulations of compression and burn of a reactor-size inertial fusion target imploded by a homogeneous thermal radiation field are presented. This target consists of a multi-layered fusion capsule that is surrounded by a solid gold casing whose radius is twice the outer capsule radius. The target absorbs about 5.4 MJ input radiation energy, about 55% of which is absorbed by the capsule while the rest is lost into the casing. The implosion yields an output thermonuclear energy of 770 MJ so that the capsule gain is of the order of 250 and the target gain is about 140. Larger values of the casing to capsule radii ratio, probably required for achieving a symmetric implosion, would lead to smaller gains, but would not change substantially the qualitative physics aspects discussed in this paper.

AB - One-dimensional numerical simulations of compression and burn of a reactor-size inertial fusion target imploded by a homogeneous thermal radiation field are presented. This target consists of a multi-layered fusion capsule that is surrounded by a solid gold casing whose radius is twice the outer capsule radius. The target absorbs about 5.4 MJ input radiation energy, about 55% of which is absorbed by the capsule while the rest is lost into the casing. The implosion yields an output thermonuclear energy of 770 MJ so that the capsule gain is of the order of 250 and the target gain is about 140. Larger values of the casing to capsule radii ratio, probably required for achieving a symmetric implosion, would lead to smaller gains, but would not change substantially the qualitative physics aspects discussed in this paper.

KW - Fusion reactors and thermonuclear power studies

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DO - 10.1007/BF02780596

M3 - 文章

AN - SCOPUS:51249168526

SN - 0369-3546

VL - 106

SP - 1919

EP - 1924

JO - Il Nuovo Cimento A

JF - Il Nuovo Cimento A

IS - 12

ER -

Simulations of compression and thermonuclear burn of a radiation-driven inertial-fusion target

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