Manipulation of laser-accelerated proton beam spatial distribution by laser machined microstructure targets

Li, D. Y.; Yang, Taoxi; Wu, Mei; Cheng, Humin; Li, Y. Z.; Xia, Yadong; Yan, Yue; Geng, Yixing; Zhao, Yanying; Lin, Chen; Yan, Xueqing

doi:10.1063/5.0062601

Cited by 4 publications

(1 citation statement)

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“…Another strategy consists of the use of deuterated targets to achieve d(d, n) 3 He, 7 Li(d, n) 8 Be, and 9 Be(d, n) 10 B reactions [27][28][29]. Lastly, neutrons are generated via proton acceleration and 9 Be(p, n) 9 B, 7 Li(p, n) 7 Be, and 63 Cu(p, n) 63 Zn nuclear reactions [29][30][31][32]. As shown in Ref.…”

Section: Introductionmentioning

confidence: 99%

Laser-Driven Neutron Generation with Near-Critical Targets and Application to Materials Characterization

2023

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Laser-driven neutrons arouse outstanding interest because of their promising uses in several fields, from basic science to materials inspection. Many experiments achieved neutron yields [10 8 − 10 10 n/(sr s)] suitable for applications. These results were obtained by exploiting high-energy (approximately 10-100 J) lasers working at low repetition rates. Instead, adopting advanced target configurations like near-critical double-layer targets (DLTs) and compact, commercial lasers was slightly considered. Here, a theoretical study is performed to address neutron generation with commercial (40-400 TW, 1-15 J) systems and DLTs. We investigate proton acceleration and interaction with various materials to induce (p, n) reactions. DLTs allow achieving 1-2 orders of magnitude larger neutron yields and maximum energies 3 times higher than with single-layer targets. Then, the feasibility of two materials characterization techniques, namely fast neutron activation analysis and pulsed fast neutron resonance radiography, is assessed. The results indicate that they can be performed with commercial lasers and DLTs.

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Section: Introductionmentioning

confidence: 99%

Laser-Driven Neutron Generation with Near-Critical Targets and Application to Materials Characterization

2023

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Spatial distribution modulation of laser-accelerated charged particles with micro-tube structures

et al. 2023

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We present experimental studies on the spatial distribution of charged particles using a linearly polarized femtosecond laser interacting with a micro-structure target composed of micro-tube structure and planar foil. For protons, a six-lobed structure was observed in the low-energy region, while a smaller angular divergence was measured in the high-energy region. Electron distribution exhibits a circular distribution at low energies and double-lobed structure at high energies. These results are well reproduced by 3D particle-in-cell simulations, showing that the profile of electrons driven by a laser pulse is manipulated by the micro-tube structure, which maps into the spatial distribution of protons via a strong charge separation field. These results demonstrate the effect of micro-structures on laser-driven particle sources and provide a possible approach for spatial manipulation of the particle beams.

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Energetic laser-driven proton beams from near-critical-density double-layer targets under moderate relativistic intensities

et al. 2023

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Double-layer targets composed of near-critical-density carbon nanotube foams (CNFs) and solid foils have shown their advantages in laser-driven ion acceleration under high relativistic intensity. Here, we report the experimental and numerical results on the laser-accelerated proton beams from such targets under moderate relativistic intensities [Formula: see text]. 40-TW femtosecond laser pulses were used to irradiate CNF-based double-layer targets. Compared to single-layer targets, significant enhancements on the cutoff energy and numbers of ions were observed. It was found that the CNF layer also leads to a larger divergence angle and a more homogeneous spatial distribution profile of the proton beam. Particle-in-cell simulations reveal the reason for the enhanced proton acceleration. It is found that the lateral electric field and the strong magnetic field built by the directly accelerated electrons from the CNF layer contribute to the enlarged divergence angle.

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Manipulation of laser-accelerated proton beam spatial distribution by laser machined microstructure targets

Cited by 4 publications

References 50 publications

Laser-Driven Neutron Generation with Near-Critical Targets and Application to Materials Characterization

Laser-Driven Neutron Generation with Near-Critical Targets and Application to Materials Characterization

Spatial distribution modulation of laser-accelerated charged particles with micro-tube structures

Energetic laser-driven proton beams from near-critical-density double-layer targets under moderate relativistic intensities

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