Optimization of laser-nanowire target interaction to increase the proton acceleration efficiency

Dozières, Maylis; Petrov, G. M.; Forestier-Colleoni, P.; Campbell, Paul; Krushelnick, K.; Maksimchuk, A.; McGuffey, C.; Kaymak, Vural; Pukhov, A.; Capeluto, M. G.; Hollinger, R.; Shlyaptsev, Vyacheslav N.; Rocca, J. J.; Beg, F. N.

doi:10.1088/1361-6587/ab157c

Cited by 31 publications

(28 citation statements)

References 33 publications

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“…They show a measured hot electron temperature increase by a factor of 2 at lower laser intensity. Secondly, Dozières et al 51 used NW targets and obtained a maximum energy enhancement factor in the range 1.5–2. In the same work, an experimental evaluation of the influence of d and g was performed, recommending a thorough evaluation of influence of length l in a subsequent study.…”

Section: Introductionmentioning

confidence: 99%

“…The effect of the NW’s geometrical parameters are related to theoretical models for plasma expansion in vacuum 52 . The experimental study is complementary to Dozières et al 51 and focuses on the NW length l as the main investigated parameter. Using experimental NW targets, we find average proton enhancement ratios of 2 and 3 for maximum energy and temperature respectively, as well as multiple-fold proton number enhancement.…”

Section: Introductionmentioning

confidence: 99%

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Enhanced laser-driven proton acceleration using nanowire targets

Vallières

Salvadori

Permogorov

et al. 2021

Sci Rep

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Laser-driven proton acceleration is a growing field of interest in the high-power laser community. One of the big challenges related to the most routinely used laser-driven ion acceleration mechanism, Target-Normal Sheath Acceleration (TNSA), is to enhance the laser-to-proton energy transfer such as to maximize the proton kinetic energy and number. A way to achieve this is using nanostructured target surfaces in the laser-matter interaction. In this paper, we show that nanowire structures can increase the maximum proton energy by a factor of two, triple the proton temperature and boost the proton numbers, in a campaign performed on the ultra-high contrast 10 TW laser at the Lund Laser Center (LLC). The optimal nanowire length, generating maximum proton energies around 6 MeV, is around 1–2 $$\upmu$$ μ m. This nanowire length is sufficient to form well-defined highly-absorptive NW forests and short enough to minimize the energy loss of hot electrons going through the target bulk. Results are further supported by Particle-In-Cell simulations. Systematically analyzing nanowire length, diameter and gap size, we examine the underlying physical mechanisms that are provoking the enhancement of the longitudinal accelerating electric field. The parameter scan analysis shows that optimizing the spatial gap between the nanowires leads to larger enhancement than by the nanowire diameter and length, through increased electron heating.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Enhanced laser-driven proton acceleration using nanowire targets

Vallières

Salvadori

Permogorov

et al. 2021

Sci Rep

View full text Add to dashboard Cite

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“…The interaction of relativistically intense laser pulses with solid targets has stimulated considerable interest because of its practical applications in laser-driven particle acceleration [1][2][3][4][5][6][7] , high-brightness ultrafast hard X-ray and K α source [8][9][10][11] , cancer treatment [12,13] , fast ignition in inertial confinement fusion [14] , etc. A crucial issue, in all these applications, is to produce high-quality forward hot electrons efficiently.…”

Section: Introductionmentioning

confidence: 99%

Generation mechanism of 100 MG magnetic fields in the interaction of ultra-intense laser pulse with nanostructured target

Tian

Cai

Zhang

et al. 2020

High Pow Laser Sci Eng

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Experimental and simulation data [Moreau et al., Plasma Phys. Control. Fusion 62, 014013 (2019); Kaymak et al., Phys. Rev. Lett. 117, 035004 (2016)] indicate that self-generated magnetic fields play an important role in enhancing the flux and energy of relativistic electrons accelerated by ultra-intense laser pulse irradiation with nanostructured arrays. A fully relativistic analytical model for the generation of the magnetic field based on electron magneto-hydrodynamic description is presented here. The analytical model shows that this self-generated magnetic field originates in the nonparallel density gradient and fast electron current at the interfaces of a nanolayered target. A general formula for the self-generated magnetic field is found, which closely agrees with the simulation scaling over the relevant intensity range. The result is beneficial to the experimental designs for the interaction of the laser pulse with the nanostructured arrays to improve laser-to-electron energy coupling and the quality of forward hot electrons.

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“…1. A MST is a solid planar target with fabricated fine structures, such as layers 22 , wires [23][24][25][26][27][28] , slots 29 or holes 30 on its surface. By the surface modulation, the interaction between laser and target can be changed from "surface heating" to "volume heating", thus increasing laser absorption and electron heating 25 .…”

mentioning

confidence: 99%

“…By the surface modulation, the interaction between laser and target can be changed from "surface heating" to "volume heating", thus increasing laser absorption and electron heating 25 . MSTs have been widely used in the Kα-rays production 23,24 , electron acceleration 22,25,26,30 , ion acceleration 27,29 and neutron generation 28 . Here, we firstly propose to use a MST to enhance positron production.…”

mentioning

confidence: 99%

Copious positron production by femto-second laser via absorption enhancement in a microstructured surface target

Wang

Yin

Wang

et al. 2020

Sci Rep

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Laser-driven positron production is expected to provide a non-radioactive, controllable, radiation tunable positron source in laboratories. We propose a novel approach of positron production by using a femto-second laser irradiating a microstructured surface target combined with a high-Z converter. By numerical simulations, it is shown that both the temperature and the maximum kinetic energy of electrons can be greatly enhanced by using a microstructured surface target instead of a planar target. When these energetic electrons shoot into a high Z converter, copious positrons are produced via Bethe-Heitler mechanism. With a laser (wavelength λ = 1 μm) with duration ~36 fs, intensity ~5.5 × 10 20 W/cm 2 and energy ~6 Joule, ~10 9 positrons can be obtained.

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Optimization of laser-nanowire target interaction to increase the proton acceleration efficiency

Cited by 31 publications

References 33 publications

Enhanced laser-driven proton acceleration using nanowire targets

Enhanced laser-driven proton acceleration using nanowire targets

Generation mechanism of 100 MG magnetic fields in the interaction of ultra-intense laser pulse with nanostructured target

Copious positron production by femto-second laser via absorption enhancement in a microstructured surface target

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