A transportable laser-plasma accelerator in the MeV range

Erwan Morel; Olena Kononenko; Jonathan Wheeler; Achraf Ayeb; Pascal Rousseau; Magali Lozano; Amar Tafzi; Lorenzo Martelli; Yves Bernard André; Sara Rushe Palacios; Xuan Quyen Dinh; Jean Philippe Denis; Henri Kraft; Philippe Demengeot; Aurélien Houard; Cedric Thaury

doi:10.1038/s41598-025-14967-0

A transportable laser-plasma accelerator in the MeV range

Erwan Morel
, Olena Kononenko
, Jonathan Wheeler
, Achraf Ayeb
, Pascal Rousseau
, Magali Lozano
, Amar Tafzi
, Lorenzo Martelli
, Yves Bernard André
, Sara Rushe Palacios
, Xuan Quyen Dinh
, Jean Philippe Denis
, Henri Kraft
, Philippe Demengeot
, Aurélien Houard
, Cedric Thaury

Research output: Contribution to journal › Article › peer-review

Abstract

Laser-plasma accelerators emerge as ultra-compact and versatile sources for numerous applications. Although the acceleration length is short (a few millimeters), they typically require large-scale infrastructures including ultra-high-power lasers, vacuum chambers and strict stability for temperature and humidity. As a result, most experiments are conducted in laboratories in large areas with controlled environments. Here, we present a highly compact (footprint of ~ 9 m²) and transportable system capable of generating electrons and photons in the MeV range at high repetition rates (up to 10 Hz) with average charge levels of 0.5 nC and up to 1 nC. This achievement shows the feasibility of performing laser-plasma acceleration outside of laboratory environments with a transportable system, significantly expanding the potential for practical applications.

Original language	English
Article number	29008
Journal	Scientific Reports
Volume	15
Issue number	1
DOIs	https://doi.org/10.1038/s41598-025-14967-0
Publication status	Published - 1 Dec 2025

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Cite this

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abstract = "Laser-plasma accelerators emerge as ultra-compact and versatile sources for numerous applications. Although the acceleration length is short (a few millimeters), they typically require large-scale infrastructures including ultra-high-power lasers, vacuum chambers and strict stability for temperature and humidity. As a result, most experiments are conducted in laboratories in large areas with controlled environments. Here, we present a highly compact (footprint of \textasciitilde{} 9 m²) and transportable system capable of generating electrons and photons in the MeV range at high repetition rates (up to 10 Hz) with average charge levels of 0.5 nC and up to 1 nC. This achievement shows the feasibility of performing laser-plasma acceleration outside of laboratory environments with a transportable system, significantly expanding the potential for practical applications.",

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AU - Morel, Erwan

AU - Kononenko, Olena

AU - Wheeler, Jonathan

AU - Ayeb, Achraf

AU - Rousseau, Pascal

AU - Lozano, Magali

AU - Tafzi, Amar

AU - Martelli, Lorenzo

AU - André, Yves Bernard

AU - Palacios, Sara Rushe

AU - Dinh, Xuan Quyen

AU - Denis, Jean Philippe

AU - Kraft, Henri

AU - Demengeot, Philippe

AU - Houard, Aurélien

AU - Thaury, Cedric

PY - 2025/12/1

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AB - Laser-plasma accelerators emerge as ultra-compact and versatile sources for numerous applications. Although the acceleration length is short (a few millimeters), they typically require large-scale infrastructures including ultra-high-power lasers, vacuum chambers and strict stability for temperature and humidity. As a result, most experiments are conducted in laboratories in large areas with controlled environments. Here, we present a highly compact (footprint of ~ 9 m²) and transportable system capable of generating electrons and photons in the MeV range at high repetition rates (up to 10 Hz) with average charge levels of 0.5 nC and up to 1 nC. This achievement shows the feasibility of performing laser-plasma acceleration outside of laboratory environments with a transportable system, significantly expanding the potential for practical applications.

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A transportable laser-plasma accelerator in the MeV range

Abstract

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