A Design for the High Yield Photoneutron Source Target Station

Lai, Yuxuan; Yang, Y.

doi:10.3390/ma15217674

Materials

2022

DOI: 10.3390/ma15217674

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A Design for the High Yield Photoneutron Source Target Station

Yuxuan Lai

Y. Yang

Abstract: Low energy accelerator driven neutron sources are promising candidates to obtain a neutron yield as high as 1014 n/s, which is required for a variety of applications, such as boron neutron capture therapy, neutron imaging, and neutron scattering. The methods to generate neutrons can be divided into two categories: hadron-based and photon-based methods. In order to better understand which kind of source would be the better choice for delivering a brilliant neutron beam robustly, in this paper, the underlying pr… Show more

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2024

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Cited by 2 publications

References 25 publications

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Remarkable reduction in thermal contact resistance between target and heat exchanger using TIMs in isotope neutron source accelerator

Qiu,

Mao,

Tang

et al. 2024

International Journal of Heat and Mass Transfer

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Remarkable reduction in thermal contact resistance between target and heat exchanger using TIMs in isotope neutron source accelerator

Qiu,

Mao,

Tang

et al. 2024

International Journal of Heat and Mass Transfer

View full text Add to dashboard Cite

Scaling of laboratory neutron sources based on laser wakefield-accelerated electrons using Monte Carlo simulations

Scheuren,

Jäger,

Kohl

et al. 2024

Eur. Phys. J. Plus

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Neutron sources based on laser-accelerated particles have attracted interest as they may provide a compact, cost-effective alternative to conventional sources. Recently, laser-driven neutron sources, based on ion acceleration, demonstrated neutron resonance spectroscopy, imaging and resonance imaging in first proof-of-principle experiments. To drive these sources efficiently with laser-accelerated ions, high laser pulse energies, in the range of tens to hundreds of Joules, with sub-ps pulse duration are needed. This requirement currently limits ion-based laser neutron sources to large-scale laser systems, which typically have maximum repetition rates in the order of a few shots per hour. In this paper, we investigate a potential path to circumvent these limitations by utilizing high repetition rate capable laser wakefield acceleration of electrons to drive a neutron source with high conversion efficiency. Monte Carlo simulations are performed to calculate neutron yields for various electron energies and converter materials, to determine optimal working parameters for an electron-based laser-driven neutron source. The results suggest that conversion efficiencies exceeding 25% can be achieved, depending on the electron energy and converter material. This electron-based approach could provide a neutron source with up to 10$$^{11}$$ 11 n/s with state-of-the-art laser sources ($$E_{\text {Laser}} \lesssim {1}\,{\rm J}$$ E Laser ≲ 1 J , $$\tau _{\text {Laser}} \lesssim {50}\,{\rm fs}$$ τ Laser ≲ 50 fs , $$\sim {1}\,\textrm{kHz}$$ ∼ 1 kHz ).

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A Design for the High Yield Photoneutron Source Target Station

Cited by 2 publications

References 25 publications

Remarkable reduction in thermal contact resistance between target and heat exchanger using TIMs in isotope neutron source accelerator

Remarkable reduction in thermal contact resistance between target and heat exchanger using TIMs in isotope neutron source accelerator

Scaling of laboratory neutron sources based on laser wakefield-accelerated electrons using Monte Carlo simulations

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