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Main Authors: Panontin, E., Tinguely, R. A., Ball, J. L., Grieve, A., Mackie, S., Nichols, L., Raj, P., Saltos, A. A., Singh, L., Vezinet, D., Wang, X., Wright, J. C., Rice, J.
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.04248
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author Panontin, E.
Tinguely, R. A.
Ball, J. L.
Grieve, A.
Mackie, S.
Nichols, L.
Raj, P.
Saltos, A. A.
Singh, L.
Vezinet, D.
Wang, X.
Wright, J. C.
Rice, J.
author_facet Panontin, E.
Tinguely, R. A.
Ball, J. L.
Grieve, A.
Mackie, S.
Nichols, L.
Raj, P.
Saltos, A. A.
Singh, L.
Vezinet, D.
Wang, X.
Wright, J. C.
Rice, J.
contents In thermonuclear plasmas, plasma ions undergoing nuclear reactions emit gamma-rays with energies in the MeV range. Their spectroscopy can convey much plasma information, such as the DT fusion power, the spatial and velocity distributions of the fast ions, and the plasma heating performance. In the present work, we simulate the gamma-ray emission expected in the SPARC tokamak during a primary reference discharge, when the tokamak is expected to generate $140$ MW of fusion power and reach an energy gain factor of $Q\approx11$. We focus particularly T(D, $γ$)He-5, B-10(He-4, p $γ$)C-13 and D(He-3, $γ$)Li-5 reactions. We use realistic plasma profiles calculated with the TRANSP code and simulate radiofrequency heating of the plasma with CQL3D and TORIC. Possible locations for gamma spectrometers based on lanthanum bromide inorganic scintillators are suggested. For each, the signal-to-noise ratio of gamma-rays over neutrons is evaluated using the ray-tracing code ToFu and high fidelity Monte Carlo models (MCNP and OpenMC) to solve radiation transport in SPARC. A dedicated neutron attenuator made of high density polyethylene is scoped to allow gamma-spectroscopy during high neutron yield experiments. And finally, the performance of LaBr$_3$ detectors in reconstructing the fusion power generated by SPARC is discussed.
format Preprint
id arxiv_https___arxiv_org_abs_2605_04248
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Synthetic model of gamma-ray emission during DT experiments on the SPARC tokamak
Panontin, E.
Tinguely, R. A.
Ball, J. L.
Grieve, A.
Mackie, S.
Nichols, L.
Raj, P.
Saltos, A. A.
Singh, L.
Vezinet, D.
Wang, X.
Wright, J. C.
Rice, J.
Plasma Physics
In thermonuclear plasmas, plasma ions undergoing nuclear reactions emit gamma-rays with energies in the MeV range. Their spectroscopy can convey much plasma information, such as the DT fusion power, the spatial and velocity distributions of the fast ions, and the plasma heating performance. In the present work, we simulate the gamma-ray emission expected in the SPARC tokamak during a primary reference discharge, when the tokamak is expected to generate $140$ MW of fusion power and reach an energy gain factor of $Q\approx11$. We focus particularly T(D, $γ$)He-5, B-10(He-4, p $γ$)C-13 and D(He-3, $γ$)Li-5 reactions. We use realistic plasma profiles calculated with the TRANSP code and simulate radiofrequency heating of the plasma with CQL3D and TORIC. Possible locations for gamma spectrometers based on lanthanum bromide inorganic scintillators are suggested. For each, the signal-to-noise ratio of gamma-rays over neutrons is evaluated using the ray-tracing code ToFu and high fidelity Monte Carlo models (MCNP and OpenMC) to solve radiation transport in SPARC. A dedicated neutron attenuator made of high density polyethylene is scoped to allow gamma-spectroscopy during high neutron yield experiments. And finally, the performance of LaBr$_3$ detectors in reconstructing the fusion power generated by SPARC is discussed.
title Synthetic model of gamma-ray emission during DT experiments on the SPARC tokamak
topic Plasma Physics
url https://arxiv.org/abs/2605.04248