Enhancing the Number of High-Energy Electrons Deposited to a Compressed Pellet via Double Cones in Fast Ignition

Cai, Hong-bo; Mima, K.; Zhou, Weimin; Jozaki, Tomoyuki; Nagatomo, Hideo; Sunahara, A.; Mason, Rodney J.

doi:10.1103/physrevlett.102.245001

Cited by 81 publications

(50 citation statements)

References 16 publications

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“…Such targets have indeed been shown to enhance the number of electrons emitted toward the precompressed core. 30 In order to characterize the fast electron beam emitted at the cone tip, we follow the trajectories of about 8 ϫ 10 6 quasiparticles, which initially belong to the cone or to the preplasma. At each time step, we extract the particles crossing the cone tip ͑at z = 30.6 m͒ with an energy threshold of 500 keV.…”

Section: Formation Of Electron Currents Along the Cone Wallsmentioning

confidence: 99%

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Generation and optimization of electron currents along the walls of a conical target for fast ignition

et al. 2010

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The interaction of an ultraintense laser pulse with a conical target is studied by means of numerical particle-in-cell simulations in the context of fast ignition. The divergence of the fast electron beam generated at the tip of the cone has been shown to be a crucial parameter for the efficient coupling of the ignition laser pulse to the precompressed fusion pellet. In this paper, we demonstrate that a focused hot electron beam is produced at the cone tip, provided that electron currents flowing along the surfaces of the cone sidewalls are efficiently generated. The influence of various interaction parameters over the formation of these wall currents is investigated. It is found that the strength of the electron flows is enhanced for high laser intensities, low density targets, and steep density gradients inside the cone. The hot electron energy distribution obeys a power law for energies of up to a few MeV, with the addition of a high-energy Maxwellian tail.

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Section: Formation Of Electron Currents Along the Cone Wallsmentioning

confidence: 99%

“…They are finally emitted toward the cone axis and participate in the enhancement of the hot electrons yield. 30 The energy spectra of the fast electron beam crossing the cone tip are shown in Fig. 9 for the three different intensities.…”

Section: -5mentioning

confidence: 99%

Generation and optimization of electron currents along the walls of a conical target for fast ignition

et al. 2010

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“…As for the beam divergence, however, it is difficult to control the angular spread of fast electrons since laserplasma interactions are the strongly-non-linear phenomena. Instead of reducing the angular spread, some ideas of the guiding of the fast electron beam with large angular spread have been proposed, e.g., the double cone [4][5][6] and the resistive guiding [7][8][9][10][11][12][13]. Those are based on using of self-generated magnetic fields.…”

Section: Introductionmentioning

confidence: 99%

Control of an electron beam using strong magnetic field for efficient core heating in fast ignition

et al. 2015

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Abstract. For enhancing the core heating efficiency in electron-driven fast ignition, we proposed the fast electron beam guiding using externally applied longitudinal magnetic fields. Based on the PIC simulations for the FIREXclass experiments, we demonstrated the sufficient beam guiding performance in the collisional dense plasma by kT-class external magnetic fields for the case with moderate mirror ratio ( 10 ≤ ). Boring of the mirror field was found through the formation of magnetic pipe structure due to the resistive effects, which indicates a possibility of beam guiding in high mirror field for higher laser intensity and/or longer pulse duration.-1-

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“…By improving the contrast ratio of heating laser pulse, we have eliminated the plasma formation inside the guiding cone before the main part of the heating pulse comes, and successfully reduced the energy (or temperature) of fast electrons with keeping the energy convergence from laser to relativistic electron beam (REB) as constant [4]. As for the beam divergence, instead of the control of laser-plasma interactions to supress the angular spread of the fast electron distribution function, some guiding ideas for fast-electron beam with large beam divergence have been proposed, e.g., guiding schemes using self-generated magnetic fields (resistive guiding [5][6][7][8][9][10][11] and vacuum gap guiding [2,12,13]) and using the externally-applied magnetic fields [14][15][16][17][18]. In the present paper, the latter scheme is discussed.…”

Section: Introductionmentioning

confidence: 99%

Integrated simulation of magnetic-field-assist fast ignition laser fusion

Johzaki¹,

Nagatomo²,

Sunahara³

et al. 2016

Plasma Phys. Control. Fusion

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To enhance the core heating efficiency in fast ignition laser fusion, the concept of relativistic electron beam guiding by external magnetic fields was evaluated by integrated simulations for FIREX class targets. For the cone-attached shell target case, the core heating performance is deteriorated by applying magnetic fields since the core is considerably deformed and the most of the fast electrons are reflected due to the magnetic mirror formed through the implosion. On the other hand, in the case of cone-attached solid ball target, the implosion is more stable under the kilo-tesla-class magnetic field. In addition, feasible magnetic field configuration is formed through the implosion. As the results, the core heating efficiency becomes double by magnetic guiding. The dependence of core heating properties on the heating pulse shot timing was also investigated for the solid ball target.T. Johzaki, et al., "Integrated simulation of magnetic-field-assist fast ignition laser fusion" Prepared for submission to Plasma Phys. Control. Fusion (43rd EPS Conference on Plasma Physics)

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Enhancing the Number of High-Energy Electrons Deposited to a Compressed Pellet via Double Cones in Fast Ignition

Cited by 81 publications

References 16 publications

Generation and optimization of electron currents along the walls of a conical target for fast ignition

Generation and optimization of electron currents along the walls of a conical target for fast ignition

Control of an electron beam using strong magnetic field for efficient core heating in fast ignition

Integrated simulation of magnetic-field-assist fast ignition laser fusion

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