High resolution Thomson Parabola Spectrometer for full spectral capture of multi-species ion beams

Alejo, A.; Kar, S.; Tebartz, A.; Ahmed, H.; Astbury, S.; Carroll, D. C.; Ding, J.; Doria, D.; Higginson, A.; McKenna, P.; Neumann, Nico W.; Scott, Graeme; Wagner, F.; Roth, Markus; Borghesi, M.

doi:10.1063/1.4961028

Cited by 11 publications

(7 citation statements)

References 23 publications

(37 reference statements)

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“…Particles can be recorded with image plates 13 , or through imaging of scintillating screens 14 . The spatial distribution of particles and photons can be directly recorded [15][16][17] or particle spectrometers can be employed to separate charged particles by mass and energy with magnetic, or also with electric fields 18 . By using image plates and permanent magnets [19][20][21] , imaging can be done hours later in an external scanner and the magnetic spectrometers can be ruggedized against electromagnetic pulses of laser-matter interactions.…”

Section: Introductionmentioning

confidence: 99%

Dispersion calibration for the National Ignition Facility electron–positron–proton spectrometers for intense laser matter interactions

Linden

Ramos-Méndez

Faddegon

et al. 2021

Review of Scientific Instruments

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Electron-positron pairs, produced in intense laser-solid interactions, are diagnosed using magnetic spectrometers with image plates, such as the National Ignition Facility (NIF) Electron Positron Proton Spectrometers (EPPS). Although modeling can help infer the quantitative value, the accuracy of the models needs to be verified to ensure measurement quality. The dispersion of low-energy electrons and positrons may be affected by fringe magnetic fields near the entrance of the EPPS. We have calibrated the EPPS with six electron beams from a Siemens Oncor linear accelerator (linac) ranging in energy from 2.7-15.2 MeV as they enter the spectrometer. A Geant4 TOPAS Monte-Carlo simulation was set up to match depth dose curves and lateral profiles measured in water at 100 cm source-surface distance. An accurate relationship was established between the bending magnet current setting and the energy of the electron beam at the exit window. The simulations and measurements were used to determine the energy distributions of the six electron beams at the EPPS slit. Analysis of the scanned image plates together with the determined energy distribution arriving in the spectrometer provide improved dispersion curves for the EPPS.

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Section: Introductionmentioning

confidence: 99%

Dispersion calibration for the National Ignition Facility electron–positron–proton spectrometers for intense laser matter interactions

Linden

Ramos-Méndez

Faddegon

et al. 2021

Review of Scientific Instruments

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“…The TPS [25], consisting of a 1 T dipole magnet, electric field plates and a 400 µm pinhole faced the front side of the target at a pinhole-target distance of 125 cm and at an angle of about 10 • from the target normal. An image plate (IP) wrapped with a 5 um Al foil, was used as detector of the particle traces deflected by the TPS.…”

Section: Methodsmentioning

confidence: 99%

“…In this experiment, the ion beam emitted in the laser forward direction was not diagnosed using a TPS, thus speculations about the species, charge states and maximum energies of heavier ions accelerated from the target rear-side cannot be confirmed by TPS ion spectra. Nevertheless, on the basis of Thomson spectra obtained in other experimental run on the VULCAN PW system with similar targets and laser conditions, we can assume that the maximum energy per nucleon of Carbon/Oxygen ions accelerated in the forward direction will be below 10 MeV/u [25]. On this basis, with reasonable confidence, the TOF signal acquired for proton energies higher than about 10 MeV, which corresponds to TOF shorter than about 60 ns, can be uniquely attributed to H + .…”

Section: Fig 5a Shows a Typical Tof Signal Acquired By The Dd Placed In The Targetmentioning

confidence: 99%

TOF diagnosis of laser accelerated, high-energy protons

Scuderi

Milluzzo

Doria

et al. 2020

Nuclear Instruments and Methods in Physics Research Section A:

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Significant challenges in the detection of laser-accelerated ions result from the high flux (10 10 -10 12 ions/pulse) and the short bunch duration which are intrinsic to laser-driven sources. The development of diagnostic techniques able to operate in real-time and on a high-rep basis is a key step towards multidisciplinary applications of such non-conventional beams. Real time diagnosis of the main beam parameters for high-energy protons accelerated by the Vulcan Petawatt (VULCAN-PW) laser system has been performed using an on line diagnostics based on the Time of Flight (TOF) technique and the use of diamond detectors.Proton energy spectra have been measured for energies exceeding 30 MeV. The results show that the TOF method employing state-of-the-art detectors is a robust real-time diagnostics, able to operate efficiently under the harsh conditions occuring with kJ-class, PW laser systems, and offering the possibility to monitor on a shot-by-shot basis the main beam parameters of high intensity proton bunches for energies up to the 100 MeV level.

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“…A laser pulse of wavelength 1.054 µm, duration of ∼ 700 fs and energy up to ∼ 400 J on target, was focused onto a 25 µm-thick Al target leading to the acceleration (from surface contaminants) of protons and light ions, such as carbon and oxygen. A Thomson Parabola Spectrometer (TPS) coupled with Image Plates was placed in the backward direction at about 1.2 m from target, separating the ion species according to charge-to-mass ratio and providing the ion energy cut-off and spectra measurements using the analysis method and the calibration reported in 27,28 . A 100 µm thick polychrystalline diamond detector was placed at the target front side at about 2.35 m (P1) from the target location, with an applied voltage of 200 V. The experimental setup is shown in FIG.…”

Section: A New Procedures For Proton Energy Spectrum Reconstructionmentioning

confidence: 99%

A new energy spectrum reconstruction method for time-of-flight diagnostics of high-energy laser-driven protons

Milluzzo

Scuderi

Alejo

et al. 2019

Review of Scientific Instruments

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The Time-of-Flight (ToF) technique coupled with semiconductor-like detectors, as silicon carbide and diamond, is one of the most promising diagnostic methods for high-energy, high repetition rate, laser-accelerated ions allowing a full on-line beam spectral characterization. A new analysis method for reconstructing the energy spectrum of high-energy laser-driven ion beams from TOF signals is hereby presented and discussed. The proposed method takes into account the detector's working principle, through the accurate calculation of the energy loss in the detector active layer, using Monte Carlo simulations. The analysis method was validated against well-established diagnostics, such as the Thomson Parabola Spectrometer, during an experimental campaign carried out at the Rutherford Appleton Laboratory (RAL, UK) with the high-energy laser-driven protons accelerated by the VULCAN Petawatt laser.

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High resolution Thomson Parabola Spectrometer for full spectral capture of multi-species ion beams

Cited by 11 publications

References 23 publications

Dispersion calibration for the National Ignition Facility electron–positron–proton spectrometers for intense laser matter interactions

Dispersion calibration for the National Ignition Facility electron–positron–proton spectrometers for intense laser matter interactions

TOF diagnosis of laser accelerated, high-energy protons

A new energy spectrum reconstruction method for time-of-flight diagnostics of high-energy laser-driven protons

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