9 research outputs found

    Single-shot laser-driven neutron resonance spectroscopy for temperature profiling

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    Lan Z., Arikawa Y., Mirfayzi S.R., et al. Single-shot laser-driven neutron resonance spectroscopy for temperature profiling. Nature Communications 15, 5365 (2024); https://doi.org/10.1038/s41467-024-49142-y.The temperature measurement of material inside of an object is one of the key technologies for control of dynamical processes. For this purpose, various techniques such as laser-based thermography and phase-contrast imaging thermography have been studied. However, it is, in principle, impossible to measure the temperature of an element inside of an object using these techniques. One of the possible solutions is measurements of Doppler brooding effect in neutron resonance absorption (NRA). Here we present a method to measure the temperature of an element or an isotope inside of an object using NRA with a single neutron pulse of approximately 100 ns width provided from a high-power laser. We demonstrate temperature measurements of a tantalum (Ta) metallic foil heated from the room temperature up to 617 K. Although the neutron energy resolution is fluctuated from shot to shot, we obtain the temperature dependence of resonance Doppler broadening using a reference of a silver (Ag) foil kept to the room temperature. A free gas model well reproduces the results. This method enables element(isotope)-sensitive thermometry to detect the instantaneous temperature rise in dynamical processes

    Development of a Time-Gated Epithermal Neutron Spectrometer for Resonance Absorption Measurements Driven by a High-Intensity Laser

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    The advance of laser-driven neutron sources (LDNSs) has enabled neutron resonance spectroscopy to be performed with a single shot of a laser. In this study, we describe a detection system of epithermal (∼eV) neutrons especially designed for neutron resonance spectroscopy. A time-gated photomultiplier tube (PMT) with a high cut-off ratio was introduced for epithermal neutron detection in a high-power laser experiment at the Institute of Laser Engineering, Osaka University. We successfully reduced the PMT response to the intense hard X-ray generated as a result of the interaction between laser light and the target material. A time-gated circuit was designed to turn off the response of the PMT during the laser pulse and resume recording the signal when neutrons arrive. The time-gated PMT was coupled with a 6Li glass scintillator, serving as a time-of-flight (TOF) detector to measure the neutron resonance absorption values of 182W and 109Ag in a laser-driven epithermal neutron generation experiment. The neutron resonance peaks at 4.15 eV of 182W and 5.19 eV of 109Ag were detected after a single pulse of laser at a distance of 1.07 m

    Non-destructive inspection of water or high-pressure hydrogen gas in metal pipes by the flash of neutrons and X-rays generated by laser

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    Low-energy neutrons in the thermal and epithermal energy regions are a powerful probe to inspect water or high pressure hydrogen gas because of their large scattering cross-sections with protons. Laser-driven neutron source, whichis able to simultaneously emit different types of radiations such as X-rays, can be used for neutron and X-ray radiography in the same laser shot. In the present paper, we report the demonstration of non-destructive inspection for H2Oinside of a stainless steel pipe using a laser driven thermal neutron source, where water and stainless containers are detected by neutrons and X-rays, respectively. The simulation result indicates that this method is also able to measure accurately the hydrogen density in high-pressure hydrogen gas in metal containers

    A miniature thermal neutron source using high power lasers

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    Dataset underpinning the results presented in the article titled, "A miniature thermal neutron source using high power lasers" published in Journal of Applied Physics (2020) Absstract of the paper: The continuous improvement of high power laser technologies is recasting the prospects of small-scale neutron sources to enable scientific communities and industries performing experiments that are currently offered at extensive accelerator-driven facilities. This paper reports moderation of laser-driven fast neutrons to thermal energies using a compact modular moderator assembly. A significant thermal (25 meV) flux of 106 n/sr/pulse was measured from water and plastic moderators in a proof-of-principle experiment employing a relatively moderate power laser delivering 200 J on the target in 10 ps. Using Monte Carlo N-Particle eXtended simulations, the experimental results are reproduced and discussed
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