A scintillating fiber imaging spectrometer for active characterization of laser-driven proton beams

J. K. Patel; C. D. Armstrong; R. Wilson; M. Alderton; E. J. Dolier; T. P. Frazer; A. Horne; A. Lofrese; M. Peat; M. Woodward; B Zielbauer; R. J. Clarke; R. Deas; P. P. Rajeev; R. J. Gray; P. McKenna

doi:10.1017/hpl.2024.62

A scintillating fiber imaging spectrometer for active characterization of laser-driven proton beams

J. K. Patel^*, C. D. Armstrong, R. Wilson, M. Alderton, E. J. Dolier, T. P. Frazer, A. Horne, A. Lofrese, M. Peat, M. Woodward, B Zielbauer, R. J. Clarke, R. Deas, P. P. Rajeev, R. J. Gray, P. McKenna

^*Corresponding author for this work

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Abstract

Next generation high-power laser facilities are expected to generate hundreds-of-MeV proton beams and operate at multi-Hz repetition rates, presenting opportunities for medical, industrial and scientific applications requiring bright pulses of energetic ions. Characterizing the spectro-spatial profile of these ions at high repetition rates in the harsh radiation environments created by laser–plasma interactions remains challenging but is paramount for further source development. To address this, we present a compact scintillating fiber imaging spectrometer based on the tomographic reconstruction of proton energy deposition in a layered fiber array. Modeling indicates that spatial resolution of approximately 1 mm and energy resolution of less than 10% at proton energies of more than 20 MeV are readily achievable with existing 100 μm diameter fibers. Measurements with a prototype beam-profile monitor using 500 μm fibers demonstrate active readouts with invulnerability to electromagnetic pulses, and less than 100 Gy sensitivity. The performance of the full instrument concept is explored with Monte Carlo simulations, accurately reconstructing a proton beam with a multiple-component spectro-spatial profile.

Original language	English
Article number	e70
Number of pages	12
Journal	High Power Laser Science and Engineering
Volume	12
Early online date	3 Dec 2024
DOIs	https://doi.org/10.1017/hpl.2024.62
Publication status	Published - 3 Dec 2024

Keywords

diagnostic
high repetition-rate
ion acceleration
laser-solid interactions

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Patel-etal-HPLSE-2024-A-scintillating-fiber-imaging-spectrometer-for-active-characterisationFinal published version, 4.39 MBLicence: CC BY 4.0

1 Active
3 Finished

The new intensity frontier: exploring quantum electrodynamic plasmas
McKenna, P. (Principal Investigator)
EPSRC (Engineering and Physical Sciences Research Council)
1/06/21 → 30/05/25
Project: Research
The Integrated Initiative of European Laser Research Infrastructures (H2020 RIA) LASERLAB-EUROPE
Jaroszynski, D. (Principal Investigator)
European Commission - Horizon Europe + H2020
1/12/19 → 30/11/24
Project: Research
Nonlinear Optics and Dynamics of Relativistically Transparent Plasmas
McKenna, P. (Principal Investigator), Gray, R. (Co-investigator) & King, M. (Research Co-investigator)
EPSRC (Engineering and Physical Sciences Research Council)
1/11/17 → 31/10/22
Project: Research

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Patel, J. K., Armstrong, C. D., Wilson, R., Alderton, M., Dolier, E. J., Frazer, T. P., Horne, A., Lofrese, A., Peat, M., Woodward, M., Zielbauer, B., Clarke, R. J., Deas, R., Rajeev, P. P., Gray, R. J., & McKenna, P. (2024). A scintillating fiber imaging spectrometer for active characterization of laser-driven proton beams. High Power Laser Science and Engineering, 12, Article e70. https://doi.org/10.1017/hpl.2024.62

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title = "A scintillating fiber imaging spectrometer for active characterization of laser-driven proton beams",

abstract = "Next generation high-power laser facilities are expected to generate hundreds-of-MeV proton beams and operate at multi-Hz repetition rates, presenting opportunities for medical, industrial and scientific applications requiring bright pulses of energetic ions. Characterizing the spectro-spatial profile of these ions at high repetition rates in the harsh radiation environments created by laser–plasma interactions remains challenging but is paramount for further source development. To address this, we present a compact scintillating fiber imaging spectrometer based on the tomographic reconstruction of proton energy deposition in a layered fiber array. Modeling indicates that spatial resolution of approximately 1 mm and energy resolution of less than 10% at proton energies of more than 20 MeV are readily achievable with existing 100 μm diameter fibers. Measurements with a prototype beam-profile monitor using 500 μm fibers demonstrate active readouts with invulnerability to electromagnetic pulses, and less than 100 Gy sensitivity. The performance of the full instrument concept is explored with Monte Carlo simulations, accurately reconstructing a proton beam with a multiple-component spectro-spatial profile.",

keywords = "diagnostic, high repetition-rate, ion acceleration, laser-solid interactions",

author = "Patel, {J. K.} and Armstrong, {C. D.} and R. Wilson and M. Alderton and Dolier, {E. J.} and Frazer, {T. P.} and A. Horne and A. Lofrese and M. Peat and M. Woodward and B Zielbauer and Clarke, {R. J.} and R. Deas and Rajeev, {P. P.} and Gray, {R. J.} and P. McKenna",

year = "2024",

month = dec,

day = "3",

doi = "10.1017/hpl.2024.62",

language = "English",

volume = "12",

journal = "High Power Laser Science and Engineering",

issn = "2095-4719",

publisher = "Cambridge University Press",

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Patel, JK, Armstrong, CD, Wilson, R , Alderton, M , Dolier, EJ, Frazer, TP, Horne, A, Lofrese, A , Peat, M, Woodward, M, Zielbauer, B, Clarke, RJ, Deas, R, Rajeev, PP, Gray, RJ & McKenna, P 2024, 'A scintillating fiber imaging spectrometer for active characterization of laser-driven proton beams', High Power Laser Science and Engineering, vol. 12, e70. https://doi.org/10.1017/hpl.2024.62

TY - JOUR

T1 - A scintillating fiber imaging spectrometer for active characterization of laser-driven proton beams

AU - Patel, J. K.

AU - Armstrong, C. D.

AU - Wilson, R.

AU - Alderton, M.

AU - Dolier, E. J.

AU - Frazer, T. P.

AU - Horne, A.

AU - Lofrese, A.

AU - Peat, M.

AU - Woodward, M.

AU - Zielbauer, B

AU - Clarke, R. J.

AU - Deas, R.

AU - Rajeev, P. P.

AU - Gray, R. J.

AU - McKenna, P.

PY - 2024/12/3

Y1 - 2024/12/3

N2 - Next generation high-power laser facilities are expected to generate hundreds-of-MeV proton beams and operate at multi-Hz repetition rates, presenting opportunities for medical, industrial and scientific applications requiring bright pulses of energetic ions. Characterizing the spectro-spatial profile of these ions at high repetition rates in the harsh radiation environments created by laser–plasma interactions remains challenging but is paramount for further source development. To address this, we present a compact scintillating fiber imaging spectrometer based on the tomographic reconstruction of proton energy deposition in a layered fiber array. Modeling indicates that spatial resolution of approximately 1 mm and energy resolution of less than 10% at proton energies of more than 20 MeV are readily achievable with existing 100 μm diameter fibers. Measurements with a prototype beam-profile monitor using 500 μm fibers demonstrate active readouts with invulnerability to electromagnetic pulses, and less than 100 Gy sensitivity. The performance of the full instrument concept is explored with Monte Carlo simulations, accurately reconstructing a proton beam with a multiple-component spectro-spatial profile.

AB - Next generation high-power laser facilities are expected to generate hundreds-of-MeV proton beams and operate at multi-Hz repetition rates, presenting opportunities for medical, industrial and scientific applications requiring bright pulses of energetic ions. Characterizing the spectro-spatial profile of these ions at high repetition rates in the harsh radiation environments created by laser–plasma interactions remains challenging but is paramount for further source development. To address this, we present a compact scintillating fiber imaging spectrometer based on the tomographic reconstruction of proton energy deposition in a layered fiber array. Modeling indicates that spatial resolution of approximately 1 mm and energy resolution of less than 10% at proton energies of more than 20 MeV are readily achievable with existing 100 μm diameter fibers. Measurements with a prototype beam-profile monitor using 500 μm fibers demonstrate active readouts with invulnerability to electromagnetic pulses, and less than 100 Gy sensitivity. The performance of the full instrument concept is explored with Monte Carlo simulations, accurately reconstructing a proton beam with a multiple-component spectro-spatial profile.

KW - diagnostic

KW - high repetition-rate

KW - ion acceleration

KW - laser-solid interactions

U2 - 10.1017/hpl.2024.62

DO - 10.1017/hpl.2024.62

M3 - Article

SN - 2095-4719

VL - 12

JO - High Power Laser Science and Engineering

JF - High Power Laser Science and Engineering

M1 - e70

ER -

A scintillating fiber imaging spectrometer for active characterization of laser-driven proton beams

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Keywords

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Projects

The new intensity frontier: exploring quantum electrodynamic plasmas

The Integrated Initiative of European Laser Research Infrastructures (H2020 RIA) LASERLAB-EUROPE

Nonlinear Optics and Dynamics of Relativistically Transparent Plasmas

Cite this