Analytical Models for the Design of the LAPLAS Experiment

Piriz, A. R.; Tahir, N. A.; López, Javier Fernández; Cortázar, O. D.; Moreno, M.C. Serna; Temporal, M.; Hoffmann, D. H. H.

doi:10.1002/ctpp.200710029

Cited by 10 publications

(6 citation statements)

References 35 publications

(47 reference statements)

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“…(10,11) were then further improved by least-square fits of experimental data [28]. But up to now, no nonlinear theory of the instabilities was developed.…”

Section: Temperature-anisotropy Driven Plasma Instabilitiesmentioning

confidence: 98%

“…Thus, the magnetosheath is a space laboratory for the investigation of MHD and kinetic waves. The analysis of the formation of magnetohydrodynamic waves as well as turbulence driven by ion beams, of course on another scale, is also the aim of the future LAPLAS (Laboratory of Planetary Sciences) experiment planned for the FAIR (Facility for Antiprotons and Ion Research) facility at GSI (Gesellschaft für Schwerionenforschung) Darmstadt, which is part of the international HEDgeHOB (High Energy Density matter generated by Heavy IOn Beams) collaboration [9,10].…”

Section: Obtained Plasma Waves and Wave Turbulencementioning

confidence: 99%

See 1 more Smart Citation

Modeling of the Temperature‐Anisotropy Relaxation Time of the Earth's Magnetosheath

Meister¹,

Besser

Lebedeva

2007

Contrib. Plasma Phys.

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In the present paper, a short review of plasma waves and turbulence in the Earth's bow shock and magnetosheath is given. Magnetohydrodynamic models which are recently applied for the magnetosheath are presented. Further, results for the relaxation of the proton temperature-anisotropy in the magnetosheath by proton pitch-angle diffusion obtained for two different magnetohydrodynamic models are discussed. It is pointed out that the relaxation time is determined by the varying strength of the excitation of ion-cyclotron and mirror waves in the different magnetosheath regions. Besides, there seems to be a background wave transfer from the solar wind into the magnetosheath.

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“…(10,11) were then further improved by least-square fits of experimental data [28]. But up to now, no nonlinear theory of the instabilities was developed.…”

Section: Temperature-anisotropy Driven Plasma Instabilitiesmentioning

confidence: 98%

Section: Obtained Plasma Waves and Wave Turbulencementioning

confidence: 99%

Modeling of the Temperature‐Anisotropy Relaxation Time of the Earth's Magnetosheath

Meister¹,

Besser

Lebedeva

2007

Contrib. Plasma Phys.

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“…Other HEDP studies are conducted and planned at the existing and constructing HIB facilities of FAIR [19], HIAF [20][21][22][48][49][50], NDCX II [18,47] and an induction accelerator at High Energy Accelerator Research Organization (KEK), Tsukuba, Japan [103]. At FAIR, GSI, Darmstadt, EOS and HEDP studies are planned at various material states with phase transition, driven by HIB [97,98,[104][105][106][107][108][109][110][111][112][113][114][115]. A magnetized plasma compression [24] is also planned at FAIR, and an annular HIB illuminates a cylindrical hollow target.…”

Section: High Energy Density Physics With Heavy Ion Beammentioning

confidence: 99%

Direct-drive heavy ion beam inertial confinement fusion: a review, toward our future energy source

Kawata

2021

Advances in Physics: X

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Direct-drive heavy ion beam (HIB) inertial confinement fusion (ICF), or HIF would be a promising future energy source for society. Particle accelerators produce HIBs with precise particle energies, pulse lengths and pulse shapes with high energy efficiencies of ~30-40%. Higher energy driver efficiency means that a lower fusion energy output is required to construct a HIF power station to supply ~1 GW of electricity. A HIF power station could use about 4 to 5 MJ of HIB energy per shot at a shot rate of ~10 Hz. This review is focused on the direct-drive scheme in HIF. In directdrive fuel target HIBs deposit their energy into a shell surrounded by a denser tamping outer layer. The DT (Deuterium-Tritium) fusion fuel, with a total mass of several mg, must be compressed to about one thousand times solid density to reduce the input driver energy and to achieve an adequate burn fraction. Highdensity compression is a major challenge in ICF, requiring that non-uniformity in driver energy deposition be kept lower than a few percent. The axis of an HIB can be made to oscillate sufficiently rapidly to improve the uniformity of energy deposition.

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“…При этом риск нарушения качества КТМ в процессе доставки и позиционирования существенно уменьшается. Решение вопроса о возможном применении защитного элемента необходи-мо, так как в исходном дизайне мишени этот элемент отсутствует [8].…”

Section: концепция специализированной криогенной системыunclassified

Cryogenic Hydrogen Fuel for Controlled Inertial Confinement Fusion (Cylindrical Targets for the Laplas Experiments)

Александрова¹,

Koresheva²,

Koshelev³

et al. 2016

PAST-TF

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Для проведения экспериментов по программе инерциального термоядерного синтеза (ИТС) в схеме LAPLAS на установке FAIR с тяжелоионным драйвером требуются цилиндрические мишени с криогенным топливным ядром. В данной статье представлен подробный анализ проблемы производства и доставки таких мишеней в центр экспериментальной камеры. Предложена кон-цепция специализированного устройства на основе бесподвесного подхода для частотного пополнения экспериментов LAPLAS цилиндрическими криогенными мишенями.Ключевые слова: инерциальный термоядерный синтез (ИТС), бесподвесный подход (FST), криогенное водородное топливо. In inertial confinement fusion (ICF) research, cylindrical cryogenic targets are required to carry out the experiments according to LAPLAS scheme on FAIR facility. In this paper, a thorough analysis of the problem of such targets fabrication, delivery and positioning in the center of the experimental chamber has been made. Based on free-standing target approach, particular attention is paid to the issue of a specialized cryogenic system development intended for rep-rate supply of the LAPLAS experiments with the cylindrical cryogenic targets. CRYOGENIC HYDROGEN FUEL FOR CONTROLLED INERTIAL CONFINEMENT FUSION (CYLINDRICAL TARGETS FOR THE LAPLAS EXPERIMENTS)

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Analytical Models for the Design of the LAPLAS Experiment

Cited by 10 publications

References 35 publications

Modeling of the Temperature‐Anisotropy Relaxation Time of the Earth's Magnetosheath

Modeling of the Temperature‐Anisotropy Relaxation Time of the Earth's Magnetosheath

Direct-drive heavy ion beam inertial confinement fusion: a review, toward our future energy source

Cryogenic Hydrogen Fuel for Controlled Inertial Confinement Fusion (Cylindrical Targets for the Laplas Experiments)

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