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Laser-Driven micro-pinch breakthrough: Unlocking ultra-intense neutron sources

05.06.25 | Nuclear Science and Techniques

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The 3-D current density and 2-D magnetic fields during the pinch simulation. In the 3D image, the red color represents positive current, while the blue color represents negative current. The 2D image illustrates the magnetic field.
The 3-D current density and 2-D magnetic fields during the pinch simulation. In the 3D image, the red color represents positive current, while the blue color represents negative current. The 2D image illustrates the magnetic field. Thex-positive direction aligns with the laser propagation and the axial direction of the nanowire, whereas theyandzdirections correspond to the radial directions of the nanowire.When irradiated by the ultrashort, high-intensity laser pulses, the atoms inside the wire Credit: Guo-Qiang Zhang

Extreme Deuterium Density

The study leverages petawatt-class lasers to induce the Z-pinch effect in deuterated polyethylene nanowires. This process compresses deuterium ions to densities exceeding 1025 cm-3, creating a micro-scale environment where nuclear fusion reactions produce femtosecond-duration neutron pulses.

Revolutionizing Neutron Generation

Using advanced Particle-in-Cell (PIC) simulations, the team demonstrated that a single 300 nm nanowire irradiated by a 60-fs laser pulse achieves a peak neutron flux of 1026 cm-2s-1. The compression phase, lasting just 10 femtoseconds, generates radial ion fluxes of 1034 cm-2s-1, enabling high-yield deuterium-deuterium (D-D) and deuterium-tritium (D-T) fusion reactions. D-T reactions produce over tenfold higher neutron yields compared to D-D, with simulations predicting over 106 neutrons per pulse in optimized nanowires.

Bridging Astrophysics and Laboratory Research

The extreme conditions potential for generating neutron-rich environments, critical for studying r-process nucleosynthesis. “This method bridges the gap between astrophysical phenomena and controlled laboratory experiments,” explains Putong Wang. “The femtosecond-scale neutron bursts also enhance Time-of-Flight measurements, crucial for nuclear data accuracy.”

Technological and Scientific Implications

Beyond astrophysics, the technique’s ultra-short pulses and microscopic spatial resolution (30 nm × 30 nm) open avenues for materials science and neutron imaging. The team highlights potential applications in neutron or proton capture reactions and compact neutron sources for industrial and security sectors.

Future Directions

The researchers plan to explore instabilities in Z -pinch dynamics and optimize target parameters for diverse nuclear reactions. “By refining laser parameters and nanowire designs, we aim to push neutron fluxes closer to astrophysical extremes,” says Putong Wang. The complete study is accessible via DOI: 10.1007/s41365-025-01738-9.

Nuclear Science and Techniques

10.1007/s41365-025-01738-9

Computational simulation/modeling

Not applicable

Laser-driven micro-pinch: a pathway to ultra-intense neutrons

2-May-2025

Additional Media

The spacial and temporal profile of plasmas density and energy density.
The spacial and temporal profile of plasmas density and energy density. Here shows the profile at 1.2 μm from the top of the nanowire. The time-dependent variation of deuterium is depicted along the curve graph specifically at the section marked by the blue and red for electron. Dotted lines are time-dependent variation of energy density. Sub-fig(2) demonstrates the deuterium number density after compression.When the return electrons are pinched radially inward by Lorentz force, they induce an e Credit: Guo-Qiang Zhang
Number of fusion with carious parameters.
The corresponding neutron (D-D fusion) flux may reach 1026 cm-2s-1. When the D-T system is considered, the fusion yield flux may reach 1027 cm-2s-1. More than 106 neutron could be generated within a single pulse, if the length of nanowire is increased to 20 μm. Cascade reactions of D-D and D-T also occur within the system. Credit: Guo-Qiang Zhang
(a) is Longditudinal cross section of accumulated neutron number density. The blue curve in (b) represents the number of nuclear reactions produced per femtosecond, while the red curve depicts the time evolution of deuterium maximum density.
(a) is Longditudinal cross section of accumulated neutron number density. The blue curve in (b) represents the number of nuclear reactions produced per femtosecond, while the red curve depicts the time evolution of deuterium maximum density.Due to the extremely high particle number density, it is seen that nuclear reactions primarily take place around the axis of the nanowire. The extremely short compression leads to a burst of reactions within femtoseconds. Credit: Guo-Qiang Zhang

Keywords

Nuclear Fusion Nucleons Particle Physics

Article Information

Journal
Nuclear Science and Techniques
DOI
10.1007/s41365-025-01738-9
Method of Research
Computational simulation/modeling
Subject of Research
Not applicable
Article Publication Date
2025-05-02
Article Title
Laser-driven micro-pinch: a pathway to ultra-intense neutrons

Contact Information

Lihua Sun
Nuclear Science and Techniques (NST)
sunlihua@sinap.ac.cn

Source

Original Source
https://link.springer.com/article/10.1007/s41365-025-01738-9

How to Cite This Article

APA:
Nuclear Science and Techniques. (2025, May 6). Laser-Driven micro-pinch breakthrough: Unlocking ultra-intense neutron sources. Brightsurf News. https://www.brightsurf.com/news/19N7DG91/laser-driven-micro-pinch-breakthrough-unlocking-ultra-intense-neutron-sources.html
MLA:
"Laser-Driven micro-pinch breakthrough: Unlocking ultra-intense neutron sources." Brightsurf News, May. 6 2025, https://www.brightsurf.com/news/19N7DG91/laser-driven-micro-pinch-breakthrough-unlocking-ultra-intense-neutron-sources.html.