Fusion Energy Output Greater than the Kinetic Energy of an Imploding Shell at the National Ignition Facility

Pape, S. Le; Hopkins, L. F. Berzak; Divol, L.; Pak, A.; Dewald, E. L.; Bhandarkar, S. D.; Bennedetti, L. R.; Bunn, Thomas L.; Biener, Juergen; Crippen, J. W.; Casey, D. T.; Edgell, D. H.; Fittinghoff, D. N.; Johnson, M. Gatu; Goyon, C.; Haan, S. W.; Hatarik, R.; Havre, M.; Ho, D.; Izumi, N.; Jaquez, J.; Khan, S. F.; Kyrala, G. A.; Ma, T.; Mackinnon, Andrew; MacPhee, A. G.; MacGowan, B. J.; Meezan, N. B.; Milovich, J. L.; Millot, Marius; Michel, P.; Nagel, S. R.; Nikroo, A.; Patel, P.; Ralph, J. E.; Ross, J. S.; Rice, N.; Strozzi, D. J.; Stadermann, Michael; Volegov, P. L.; Yeamans, C. B.; Weber, Christopher; Wild, C.; Callahan, D. A.; Hurricane, O. A.

doi:10.1103/physrevlett.120.245003

Cited by 222 publications

(109 citation statements)

References 32 publications

(28 reference statements)

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“…(4) vs T from eq.(1). Omega and NIF data are derived from the experiments [25], using the Down Scatter Ratio [23,21]. Our results using the DSR method (N 4 /N 3 ) are given by the open triangle symbols in good agreement with the N 3 /N 2 ratios.…”

supporting

confidence: 56%

“…Careful methods might be devised to keep the system as close as possible to equilibrium for instance using several laser beams to compress and heat a target [21]. Nevertheless, important out of equilibrium effects might still be present [22,23,24] and prevent the optimization of nuclear fusion reactions towards a prototype of a nuclear reactor. Stimulated by these considerations we decided not to fight non-equilibrium effects but rather enhance them, i.e.…”

mentioning

confidence: 99%

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Nuclear probes of an out-of-equilibrium plasma at the highest compression

et al. 2019

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We report the highest compression reached in laboratory plasmas using eight laser beams, E laser ≈12 kJ, τ laser =2 ns in third harmonic on a CD 2 target at the ShenGuang-II Upgrade (SGII-Up) facility in Shanghai, China. We estimate the deuterium density ρ D = 2.0 ± 0.9 kg/cm 3 , and the average kinetic energy of the plasma ions less than 1 keV. The highest reached areal density Λρ D =4.8 ± 1.5 g/cm 2 was obtained from the measured ratio of the sequential ternary fusion reactions (dd→t+p and t+d→α+n) and the two body reaction fusions (dd→ 3 He+n). At such high densities, sequential ternary and also quaternary nuclear reactions become important as well (i.e. n(14.1 MeV) + 12 C → n'+ 12 C* etc.) resulting in a shift of the neutron (and proton) kinetic energies from their birth values. The Down Scatter Ratio (DSR-quaternary nuclear reactions) method, i.e. the ratio of the 10-12MeV neutrons divided by the total number of 14.1MeV neutrons produced, confirms the high densities reported above. The estimated lifetime of the highly compressed plasma is 52 ± 9 ps, much smaller than the lasers pulse duration.

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supporting

confidence: 56%

mentioning

confidence: 99%

Nuclear probes of an out-of-equilibrium plasma at the highest compression

et al. 2019

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“…While implosion symmetry in recent years has improved remarkably, allowing yields to reach 2×10 16 [11], some level of perturbation persists.…”

Section: Scaling Perturbed Simulationsmentioning

confidence: 99%

“…Their impacts have been reduced through a combination of improved laser drive symmetry control and different ablator materials [17]. Currently, the gas fill-tube is the most damaging perturbation source on the HDC implosions [11]. Methods for addressing the impact of the fill-tube [11,18] have produced the highest yield implosions to date, with neutron yields of ∼ 2×10 16 .…”

Section: Introductionmentioning

confidence: 99%

Burn regimes in the hydrodynamic scaling of perturbed inertial confinement fusion hotspots

Tong¹,

McGlinchey²,

Appelbe³

et al. 2019

Nucl. Fusion

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We present simulations of ignition and burn based on the Highfoot and High-Density Carbon indirect drive designs of the National Ignition Facility for three regimes of alpha-heating -self-heating, robust ignition and propagating burn -exploring hotspot power balance, perturbations and hydrodynamic scaling. A Monte-Carlo Particle-in-Cell charged particle transport package for the radiation-magnetohydrodynamics code Chimera was developed for this purpose, using a linked-list type data structure.The hotspot power balance between alpha-heating, electron thermal conduction and radiation was investigated in 1D for the three burn regimes. The impact of perturbations on this power balance is explored in 3D using a single Rayleigh-Taylor spike. Heat flow into the perturbation from thermal conduction and alpha-heating increases by factors of ∼2 − 3, due to sharper temperature gradients and increased proximity of the cold, dense material to the main fusion regions respectively. The radiative contribution remains largely unaffected in magnitude.Hydrodynamic scaling with capsule size and laser energy of different perturbation scenarios (a short-wavelength multi-mode and a low-mode radiation asymmetry) is explored in 3D, demonstrating the differing hydrodynamic evolution of the three alpha-heating regimes. The multi-mode yield increases faster with scale factor due to more synchronous P dV compression producing higher temperatures and densities, and therefore stronger bootstrapping of alphaheating. Effects on the hydrodynamic evolution are more prominent for stronger alpha-heating regimes, and include: reduced perturbation growth due to ablation from both fire-polishing and stronger thermal conduction; sharper temperature and density gradients at the boundary; and increased hotspot pressures which further compress the shell, increase hotspot size and induce faster re-expansion. The faster expansion into regions of weak confinement is more prominent for stronger alpha-heating regimes, and can result in loss of confinement.

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“…The fast isochoric laser heating of imploded plasma is one of the scheme to create ultra-high-energy-density (UHED) state, which is equivalent to the state at the center of the sun, for the inertial confinement fusion (ICF) science.In conventional implosion, kinetic energy of the imploded shell is converted to the internal energy of the compressed matter at the maximum compression. A UHED state with 36 Peta-Pascal (PPa) was achieved on the National Ignition Facility with 1.8 MJ of laser energy by the indirect X-ray driven implosion [7]. The OMEGA laser facility with 30 kJ of laser energy produced 5.6 PPa of UHED by the direct laser-driven implosion [8].…”

mentioning

confidence: 99%

Petapascal Pressure Driven by Fast Isochoric Heating with a Multipicosecond Intense Laser Pulse

Matsuo¹,

Higashi²,

Iwata³

et al. 2020

Phys. Rev. Lett.

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Fast isochoric laser heating is a scheme to heat a matter with relativistic-intensity (> 10 18 W/cm 2 ) laser pulse or X-ray free electron laser pulse. The fast isochoric laser heating has been studied for creating efficiently ultra-high-energy-density (UHED) state. We demonstrate an fast isochoric heating of an imploded dense plasma using a multi-picosecond kJ-class petawatt laser with an assistance of externally applied kilo-tesla magnetic fields for guiding fast electrons to the dense plasma.The UHED state with 2.2 Peta-Pascal is achieved experimentally with 4.6 kJ of total laser energy that is one order of magnitude lower than the energy used in the conventional implosion scheme. A two-dimensional particle-in-cell simulation reveals that diffusive heating from a laserplasma interaction zone to the dense plasma plays an essential role to the efficient creation of the UHED state.Power laser apparatus can inject a plenty of energy to a matter in a small volume within a short time duration. The matter becomes a high-energy-density state that is applicable to various scientific researches such as laboratory astrophysics [1] and several kind of radiation sources: X-rays, charged particles, and neutrons [2,3]. Fast isochoric heating of solid target to create such highenergy-density states have been demonstrated by short pulse laser [4] and X-ray free electron laser [5,6]. The fast isochoric laser heating of imploded plasma is one of the scheme to create ultra-high-energy-density (UHED) state, which is equivalent to the state at the center of the sun, for the inertial confinement fusion (ICF) science.In conventional implosion, kinetic energy of the imploded shell is converted to the internal energy of the compressed matter at the maximum compression. A UHED state with 36 Peta-Pascal (PPa) was achieved on the National Ignition Facility with 1.8 MJ of laser energy by the indirect X-ray driven implosion [7]. The OMEGA laser facility with 30 kJ of laser energy produced 5.6 PPa of UHED by the direct laser-driven implosion [8]. The current central ignition scheme requires enormous laser energy to create UHED state. The significant growth of hydrodynamic instabilities during the compression causes the hot spark mixing with the cold dense fuel and prevents efficient creation of UHED state.In the context of ICF, the fast isochoric heating also known as the fast ignition had been proposed as an alternative approach [9]. This approach separates compres-sion and heating processes to avoid the mixing, using a more stable compression followed by an external energy injection whose time scale is much shorter than the implosion time scale. Hence, it potentially leads to higher gain by increasing the mass of the compressed fuel .A cone-in-shell target is commonly used in the integrated fast-isochoric-heating experiments, since a dense plasma core, which is produced by the laser-driven implosion, is surrounded by a long-scale-length coronal plasma. The cone preserves a vacuum channel in the coronal plasma for the heating laser pulse to...

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Fusion Energy Output Greater than the Kinetic Energy of an Imploding Shell at the National Ignition Facility

Cited by 222 publications

References 32 publications

Nuclear probes of an out-of-equilibrium plasma at the highest compression

Nuclear probes of an out-of-equilibrium plasma at the highest compression

Burn regimes in the hydrodynamic scaling of perturbed inertial confinement fusion hotspots

Petapascal Pressure Driven by Fast Isochoric Heating with a Multipicosecond Intense Laser Pulse

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