Double differential neutron yields from thick targets used in space applications

McGirl, Natalie A.; Castellanos, L.; Srikrishna, Ashwin P.; Heilbronn, L.; Tessa, Chiara La; Rusek, A.; Sivertz, M.; Blattnig, Steve R.; Clowdsley, M. S.; Slaba, Tony C.; Zeitlin, C.

doi:10.1051/epjconf/201715304002

Cited by 2 publications

(2 citation statements)

References 7 publications

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“…Recently, it has also been recognized as the only facility in the United States currently capable of contributing to heavy ion therapy research. The facility provides a large room (10 m long from exit window to beam dump), well suited for time of flight (TOF) and double differential cross section measurements [135].…”

Section: Review Of Acceleratorsmentioning

confidence: 99%

Are Further Cross Section Measurements Necessary for Space Radiation Protection or Ion Therapy Applications? Helium Projectiles

et al. 2020

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The helium (4He) component of the primary particles in the galactic cosmic ray spectrum makes significant contributions to the total astronaut radiation exposure. 4He ions are also desirable for direct applications in ion therapy. They contribute smaller projectile fragmentation than carbon (12C) ions and smaller lateral beam spreading than protons. Space radiation protection and ion therapy applications need reliable nuclear reaction models and transport codes for energetic particles in matter. Neutrons and light ions (1H, 2H, 3H, 3He, and 4He) are the most important secondary particles produced in space radiation and ion therapy nuclear reactions; these particles penetrate deeply and make large contributions to dose equivalent. Since neutrons and light ions may scatter at large angles, double differential cross sections are required by transport codes that propagate radiation fields through radiation shielding and human tissue. This work will review the importance of 4He projectiles to space radiation and ion therapy, and outline the present status of neutron and light ion production cross section measurements and modeling, with recommendations for future needs.

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Section: Review Of Acceleratorsmentioning

confidence: 99%

Are Further Cross Section Measurements Necessary for Space Radiation Protection or Ion Therapy Applications? Helium Projectiles

et al. 2020

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“…A second problem concerns the detectors (or tools) needed to characterize neutron spectra at energies above 20 MeV. Currently, the most used detectors are organic scintillators [13] which have good energy resolution but are limited in the measurable energy range and Bonner Sphere sets [14] which have low energy resolution but a large measurable energy range.…”

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confidence: 99%

Measurement of secondary neutron spectra induced by 480 MeV proton and 430 MeV/u ⁴He beams with a thick aluminum target

Di Chicco,

Boscolo,

Luoni

et al. 2024

J. Inst.

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Knowledge of the characteristics of secondary neutrons produced by the interaction of Galactic Cosmic Radiation with spacecraft shielding materials is becoming increasingly important for predicting and mitigating biological risks of space explorers during deep-space travel. Hadron accelerators for medical applications are well suited to reproduce part of the conditions found in deep-space in terms of ion species and energies. The objectives of this work are to measure the secondary neutron spectra produced by proton and helium ion beams hitting an aluminum target with energies that correspond to the Galactic Cosmic Radiation peak during solar minimal activity and to validate and compare physical models of Monte Carlo simulations. Neutron spectra were measured with the extended-range Bonner sphere system NEMUS at two positions, 0° and 90° relative to the direction of the primary ion beam. The experimental setup consisted of 480 MeV proton and 430 MeV/u 4He beams colliding with a 30×30×63.5 cm3 aluminum target. The experimental neutron spectra were analyzed using the MAXED unfolding code and compared to several Monte Carlo simulation codes. The results show deviations in terms of the shape of the neutron energy distributions ranging between 1% and 14% and of the integral quantities of fluence and ambient dose equivalent ranging between 1% and 5.2%.

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Double differential neutron yields from thick targets used in space applications

Cited by 2 publications

References 7 publications

Are Further Cross Section Measurements Necessary for Space Radiation Protection or Ion Therapy Applications? Helium Projectiles

Are Further Cross Section Measurements Necessary for Space Radiation Protection or Ion Therapy Applications? Helium Projectiles

Measurement of secondary neutron spectra induced by 480 MeV proton and 430 MeV/u ⁴He beams with a thick aluminum target

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Double differential neutron yields from thick targets used in space applications

Cited by 2 publications

References 7 publications

Are Further Cross Section Measurements Necessary for Space Radiation Protection or Ion Therapy Applications? Helium Projectiles

Are Further Cross Section Measurements Necessary for Space Radiation Protection or Ion Therapy Applications? Helium Projectiles

Measurement of secondary neutron spectra induced by 480 MeV proton and 430 MeV/u 4He beams with a thick aluminum target

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Product

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Measurement of secondary neutron spectra induced by 480 MeV proton and 430 MeV/u ⁴He beams with a thick aluminum target