Tabletop particle blaster: How tiny nozzles and lasers could replace giant accelerators
en-GBde-DEes-ESfr-FR

Tabletop particle blaster: How tiny nozzles and lasers could replace giant accelerators

02/06/2025 The University of Osaka
Researchers at The University of Osaka have proposed "micronozzle acceleration"—a novel method for generating giga-electron-volt proton beams using ultra-intense lasers.

Osaka, Japan - Proton beams with giga-electron-volt (GeV) energies—once thought to be achievable only with massive particle accelerators—may soon be generated in compact setups thanks to a breakthrough by researchers at The University of Osaka.

A team led by Professor Masakatsu Murakami has developed a novel concept called micronozzle acceleration (MNA). By designing a microtarget with tiny nozzle-like features and irradiating it with ultraintense, ultrashort laser pulses, the team successfully demonstrated—through advanced numerical simulations—the generation of high-quality, GeV-class proton beams: a world-first achievement.

Unlike traditional laser-based acceleration methods that use flat targets and reach energy limits below 100 mega-electron-volt (MeV) (1 GeV = 1000 MeV), the micronozzle structure enables sustained, stepwise acceleration of protons within a powerful quasi-static electric field created inside the target. This new mechanism allows proton energies to exceed 1 GeV, with excellent beam quality and stability.

“This discovery opens a new door for compact, high-efficiency particle acceleration,” says Prof. Murakami. “We believe this method has the potential to revolutionize fields such as laser fusion energy, advanced radiotherapy, and even laboratory-scale astrophysics.”

The implications are wide-reaching:
- Energy: Supports fast ignition schemes in laser-driven nuclear fusion.
- Medicine: Enables more compact and precise systems for proton cancer therapy.
- Fundamental Science: Creates conditions to simulate extreme astrophysical environments and probe matter under ultra-strong magnetic fields.
The study, based on simulations performed on the SQUID supercomputer at The University of Osaka, marks the first-ever theoretical demonstration of compact GeV proton acceleration using microstructured targets.

###
The article, “Generation of giga-electron-volt proton beams by micronozzle acceleration,” was published in Scientific Reports at DOI: https://doi.org/10.1038/s41598-025-03385-x
https://resou.osaka-u.ac.jp/en
Title: Generation of giga-electron-volt proton beams by micronozzle acceleration
Journal: Scientific Reports (Nature Publishing Group)
Authors: M. Murakami, D. Balusu, S. Maruyama, Y. Murakami, B. Ramakrishna
DOI: 10.1038/s41598-025-03385-x
Funded by: Japan Society for the Promotion of Science
Personal Homepage (YouTube): https://www.youtube.com/watch?v=eL4w1uGRk4U
Attached files
  • Fig .1 Conceptual illustration of micronozzle acceleration (MNA). A solid hydrogen rod is embedded in an aluminum micronozzle, which channels and focuses plasma flow to optimize proton acceleration., Original content, No restrictions., Masakatsu Murakami
  • Fig. 2 Concept of Micronozzle Acceleration (MNA).The MNA (Micro-Nozzle Acceleration) target employs a micronozzle housing a solid hydrogen rod (H-rod), precisely placed near the nozzle neck to maximize proton yield. Acting as a "power lens," the micronozzle focuses the incident laser energy onto the H-rod, enabling efficient and localized energy deposition. This configuration significantly boosts proton acceleration near the nozzle exit, outperforming setups lacking the nozzle structure., CC BY NC-ND, 2025, Masakatsu Murakami, et al., Generation of giga-electron-volt proton beams by micronozzle acceleration, Scientific Reports
02/06/2025 The University of Osaka
Regions: Asia, Japan
Keywords: Applied science, Computing, Science, Physics

Disclaimer: AlphaGalileo is not responsible for the accuracy of content posted to AlphaGalileo by contributing institutions or for the use of any information through the AlphaGalileo system.

Testimonials

For well over a decade, in my capacity as a researcher, broadcaster, and producer, I have relied heavily on Alphagalileo.
All of my work trips have been planned around stories that I've found on this site.
The under embargo section allows us to plan ahead and the news releases enable us to find key experts.
Going through the tailored daily updates is the best way to start the day. It's such a critical service for me and many of my colleagues.
Koula Bouloukos, Senior manager, Editorial & Production Underknown
We have used AlphaGalileo since its foundation but frankly we need it more than ever now to ensure our research news is heard across Europe, Asia and North America. As one of the UK’s leading research universities we want to continue to work with other outstanding researchers in Europe. AlphaGalileo helps us to continue to bring our research story to them and the rest of the world.
Peter Dunn, Director of Press and Media Relations at the University of Warwick
AlphaGalileo has helped us more than double our reach at SciDev.Net. The service has enabled our journalists around the world to reach the mainstream media with articles about the impact of science on people in low- and middle-income countries, leading to big increases in the number of SciDev.Net articles that have been republished.
Ben Deighton, SciDevNet

We Work Closely With...

  • e
  • The Research Council of Norway
  • SciDevNet
  • Swiss National Science Foundation
  • iesResearch
Copyright 2025 by AlphaGalileo Terms Of Use Privacy Statement