Enhanced Energy, Conversion Efficiency and Collimation of Protons Driven by High-Contrast and Ultrashort Laser Pulses

Weipeng Yao; Ronan Lelièvre; Tessa Waltenspiel; Itamar Cohen; Amokrane Allaoua; Patrizio Antici; Arie Beck; Erez Cohen; Xavier Davoine; Emmanuel d’Humières; Quentin Ducasse; Evgeny Filippov; Cort Gautier; Laurent Gremillet; Pavlos Koseoglou; David Michaeli; Dimitrios Papadopoulos; Sergey Pikuz; Ishay Pomerantz; Francois Trompier; Yuran Yuan; Francois Mathieu; Julien Fuchs

doi:10.3390/app14146101

Enhanced Energy, Conversion Efficiency and Collimation of Protons Driven by High-Contrast and Ultrashort Laser Pulses

Weipeng Yao^*, Ronan Lelièvre, Tessa Waltenspiel, Itamar Cohen, Amokrane Allaoua, Patrizio Antici, Arie Beck, Erez Cohen, Xavier Davoine, Emmanuel d’Humières, Quentin Ducasse, Evgeny Filippov, Cort Gautier, Laurent Gremillet, Pavlos Koseoglou, David Michaeli, Dimitrios Papadopoulos, Sergey Pikuz, Ishay Pomerantz, Francois TrompierYuran Yuan, Francois Mathieu, Julien Fuchs^*

^*Corresponding author for this work

School of Physics and Astronomy

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

1 Scopus citations

Abstract

Progress in laser-driven proton acceleration requires increasing the proton maximum energy and laser-to-proton conversion efficiency while reducing the divergence of the proton beam. However, achieving all these qualities simultaneously has proven challenging experimentally, with the increase in beam energy often coming at the cost of beam quality. Numerical simulations suggest that coupling multi-PW laser pulses with ultrathin foils could offer a route for such simultaneous improvement. Yet, experimental investigations have been limited by the scarcity of such lasers and the need for very stringent temporal contrast conditions to prevent premature target expansion before the pulse maximum. Here, combining the newly commissioned Apollon laser facility that delivers high-power ultrashort (∼ (Formula presented.)) pulses with a double plasma mirror scheme to enhance its temporal contrast, we demonstrate the generation of up to 35 MeV protons with only 5 J of laser energy. This approach also achieves improved laser-to-proton energy conversion efficiency, reduced beam divergence, and optimized spatial beam profile. Therefore, despite the laser energy losses induced by the plasma mirror, the proton beams produced by this method are enhanced on all accounts compared to those obtained under standard conditions. Particle-in-cell simulations reveal that this improvement mainly results from a better space–time synchronization of the maximum of the accelerating charge-separation field with the proton bunch.

Original language	English
Article number	6101
Journal	Applied Sciences (Switzerland)
Volume	14
Issue number	14
DOIs	https://doi.org/10.3390/app14146101
State	Published - Jul 2024

Funding

Funders	Funder number
CNRS
IdEx University of Bordeaux
French Ministry of Europe and Foreign Affairs
French Ministry of Higher Education and Research
Natural Sciences and Engineering Research Council of Canada
Compute Canada
European Research Council
Grand Research Program
Horizon 2020
IRSN
Horizon 2020 Framework Programme	787539
PAZY Foundation	435/2023

Keywords

high-power lasers
laser-driven ion acceleration
particle-in-cell simulation
plasma mirror

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10.3390/app14146101

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Yao, W., Lelièvre, R., Waltenspiel, T., Cohen, I., Allaoua, A., Antici, P., Beck, A., Cohen, E., Davoine, X., d’Humières, E., Ducasse, Q., Filippov, E., Gautier, C., Gremillet, L., Koseoglou, P., Michaeli, D., Papadopoulos, D., Pikuz, S., Pomerantz, I., ... Fuchs, J. (2024). Enhanced Energy, Conversion Efficiency and Collimation of Protons Driven by High-Contrast and Ultrashort Laser Pulses. Applied Sciences (Switzerland), 14(14), Article 6101. https://doi.org/10.3390/app14146101

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title = "Enhanced Energy, Conversion Efficiency and Collimation of Protons Driven by High-Contrast and Ultrashort Laser Pulses",

abstract = "Progress in laser-driven proton acceleration requires increasing the proton maximum energy and laser-to-proton conversion efficiency while reducing the divergence of the proton beam. However, achieving all these qualities simultaneously has proven challenging experimentally, with the increase in beam energy often coming at the cost of beam quality. Numerical simulations suggest that coupling multi-PW laser pulses with ultrathin foils could offer a route for such simultaneous improvement. Yet, experimental investigations have been limited by the scarcity of such lasers and the need for very stringent temporal contrast conditions to prevent premature target expansion before the pulse maximum. Here, combining the newly commissioned Apollon laser facility that delivers high-power ultrashort (∼ (Formula presented.)) pulses with a double plasma mirror scheme to enhance its temporal contrast, we demonstrate the generation of up to 35 MeV protons with only 5 J of laser energy. This approach also achieves improved laser-to-proton energy conversion efficiency, reduced beam divergence, and optimized spatial beam profile. Therefore, despite the laser energy losses induced by the plasma mirror, the proton beams produced by this method are enhanced on all accounts compared to those obtained under standard conditions. Particle-in-cell simulations reveal that this improvement mainly results from a better space–time synchronization of the maximum of the accelerating charge-separation field with the proton bunch.",

keywords = "high-power lasers, laser-driven ion acceleration, particle-in-cell simulation, plasma mirror",

author = "Weipeng Yao and Ronan Leli{\`e}vre and Tessa Waltenspiel and Itamar Cohen and Amokrane Allaoua and Patrizio Antici and Arie Beck and Erez Cohen and Xavier Davoine and Emmanuel d{\textquoteright}Humi{\`e}res and Quentin Ducasse and Evgeny Filippov and Cort Gautier and Laurent Gremillet and Pavlos Koseoglou and David Michaeli and Dimitrios Papadopoulos and Sergey Pikuz and Ishay Pomerantz and Francois Trompier and Yuran Yuan and Francois Mathieu and Julien Fuchs",

note = "Publisher Copyright: {\textcopyright} 2024 by the authors.",

year = "2024",

month = jul,

doi = "10.3390/app14146101",

language = "אנגלית",

volume = "14",

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Yao, W, Lelièvre, R, Waltenspiel, T, Cohen, I, Allaoua, A, Antici, P, Beck, A, Cohen, E, Davoine, X, d’Humières, E, Ducasse, Q, Filippov, E, Gautier, C, Gremillet, L, Koseoglou, P, Michaeli, D, Papadopoulos, D, Pikuz, S, Pomerantz, I, Trompier, F, Yuan, Y, Mathieu, F & Fuchs, J 2024, 'Enhanced Energy, Conversion Efficiency and Collimation of Protons Driven by High-Contrast and Ultrashort Laser Pulses', Applied Sciences (Switzerland), vol. 14, no. 14, 6101. https://doi.org/10.3390/app14146101

TY - JOUR

T1 - Enhanced Energy, Conversion Efficiency and Collimation of Protons Driven by High-Contrast and Ultrashort Laser Pulses

AU - Yao, Weipeng

AU - Lelièvre, Ronan

AU - Waltenspiel, Tessa

AU - Cohen, Itamar

AU - Allaoua, Amokrane

AU - Antici, Patrizio

AU - Beck, Arie

AU - Cohen, Erez

AU - Davoine, Xavier

AU - d’Humières, Emmanuel

AU - Ducasse, Quentin

AU - Filippov, Evgeny

AU - Gautier, Cort

AU - Gremillet, Laurent

AU - Koseoglou, Pavlos

AU - Michaeli, David

AU - Papadopoulos, Dimitrios

AU - Pikuz, Sergey

AU - Pomerantz, Ishay

AU - Trompier, Francois

AU - Yuan, Yuran

AU - Mathieu, Francois

AU - Fuchs, Julien

PY - 2024/7

Y1 - 2024/7

N2 - Progress in laser-driven proton acceleration requires increasing the proton maximum energy and laser-to-proton conversion efficiency while reducing the divergence of the proton beam. However, achieving all these qualities simultaneously has proven challenging experimentally, with the increase in beam energy often coming at the cost of beam quality. Numerical simulations suggest that coupling multi-PW laser pulses with ultrathin foils could offer a route for such simultaneous improvement. Yet, experimental investigations have been limited by the scarcity of such lasers and the need for very stringent temporal contrast conditions to prevent premature target expansion before the pulse maximum. Here, combining the newly commissioned Apollon laser facility that delivers high-power ultrashort (∼ (Formula presented.)) pulses with a double plasma mirror scheme to enhance its temporal contrast, we demonstrate the generation of up to 35 MeV protons with only 5 J of laser energy. This approach also achieves improved laser-to-proton energy conversion efficiency, reduced beam divergence, and optimized spatial beam profile. Therefore, despite the laser energy losses induced by the plasma mirror, the proton beams produced by this method are enhanced on all accounts compared to those obtained under standard conditions. Particle-in-cell simulations reveal that this improvement mainly results from a better space–time synchronization of the maximum of the accelerating charge-separation field with the proton bunch.

AB - Progress in laser-driven proton acceleration requires increasing the proton maximum energy and laser-to-proton conversion efficiency while reducing the divergence of the proton beam. However, achieving all these qualities simultaneously has proven challenging experimentally, with the increase in beam energy often coming at the cost of beam quality. Numerical simulations suggest that coupling multi-PW laser pulses with ultrathin foils could offer a route for such simultaneous improvement. Yet, experimental investigations have been limited by the scarcity of such lasers and the need for very stringent temporal contrast conditions to prevent premature target expansion before the pulse maximum. Here, combining the newly commissioned Apollon laser facility that delivers high-power ultrashort (∼ (Formula presented.)) pulses with a double plasma mirror scheme to enhance its temporal contrast, we demonstrate the generation of up to 35 MeV protons with only 5 J of laser energy. This approach also achieves improved laser-to-proton energy conversion efficiency, reduced beam divergence, and optimized spatial beam profile. Therefore, despite the laser energy losses induced by the plasma mirror, the proton beams produced by this method are enhanced on all accounts compared to those obtained under standard conditions. Particle-in-cell simulations reveal that this improvement mainly results from a better space–time synchronization of the maximum of the accelerating charge-separation field with the proton bunch.

KW - high-power lasers

KW - laser-driven ion acceleration

KW - particle-in-cell simulation

KW - plasma mirror

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ER -

Enhanced Energy, Conversion Efficiency and Collimation of Protons Driven by High-Contrast and Ultrashort Laser Pulses

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