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== Useful GitHub Repositories for Neutronics in Nuclear Fusion ==
= Neutron Detectors in Fusion Tokamaks =
 
The progress in neutron detectors for fusion devices has enabled increasingly precise measurements of neutron flux, energy spectra, and spatial emission profiles. Advances in detector technology and modeling now allow researchers to better assess key plasma parameters, including fusion power, ion temperature, and fuel composition.
 
{| class="wikitable sortable"
! Method
! Principle
! Measures
! Typical Technology
! Pros
! Cons
! Use in Tokamaks
! Numerical Tools
|-
| Neutron Counters and Flux Monitors<ref name="Counters"/>
| Neutrons induce charged particle reactions in gas or fissile material
| Neutron flux / total yield
| ³He, BF₃ counters, U-235 / U-238 fission chambers, ionization chambers
| Robust, wide dynamic range, gamma discrimination
| Limited energy information, saturation at very high flux
| Real-time flux monitoring, fusion power measurement
| MCNP, FLUKA
|-
| Activation Detectors<ref name="Activation"/>
| Neutrons induce activation in target material
| Time-integrated neutron fluence
| Metal foils (Au, In, Al, Nb), delayed neutron activation
| Simple, high flux tolerant, immune to EM noise
| Not real-time, requires post-shot analysis
| Absolute neutron yield calibration, benchmarking
| MCNP, GEANT4
|-
| Neutron Spectrometers (Recoil-Based)<ref name="Spectrometers"/>
| Neutrons induce recoil of charged particles
| Neutron energy spectrum
| Magnetic Proton Recoil (MPR), proton recoil telescopes, silicon detectors
| High energy resolution, provides ion temperature and fuel ratio
| Bulky, sensitive to background, complex shielding
| Plasma ion temperature, fuel ratio, fast-ion studies
| MCNP, GEANT4
|-
| Solid-State Neutron Detectors<ref name="SolidState"/>
| Neutrons induce charge in solid-state detector
| Flux and partial spectral information
| CVD diamond, SiC detectors
| Compact, fast response, radiation hard
| Limited efficiency, calibration complexity
| ITER-relevant diagnostics, high-flux measurements
| GEANT4
|-
| Scintillator-Based Neutron Detectors<ref name="Scintillators"/>
| Neutrons induce light pulses in scintillator
| Flux, timing, limited spectral information
| Liquid or plastic scintillators + PMT/SiPM
| Fast, allows neutron/gamma discrimination
| Radiation damage, sensitive to magnetic fields
| Time-resolved neutron flux, pulse shape discrimination
| GEANT4
|-
| Neutron Cameras<ref name="Cameras"/>
| Neutrons induce signals in collimated detectors
| Spatial neutron emissivity (line-integrated)
| Scintillator or diamond arrays with collimation
| Spatially resolved plasma information
| Heavy shielding, complex neutronics
| Plasma profile mapping, fast-ion studies
| MCNP, GEANT4
|}
 
 
= Useful GitHub Repositories for Neutronics in Nuclear Fusion =


Several GitHub repositories provide tools and workflows that are highly valuable for neutronics development in fusion research:
Several GitHub repositories provide tools and workflows that are highly valuable for neutronics development in fusion research:
Line 110: Line 180:
# '''fusion-energy''' – This is a massive and highly recommended GitHub organization for any neutron physicist working in fusion. It hosts a wide range of projects for fusion neutronics and contains tools like fusion_neutron_utils, fusion_neutronics_workflow, and OpenMC plasma source utilities. These projects enable neutron source generation, Monte Carlo transport simulations, activation and decay analysis, and 3D modeling of fusion device neutronics, making it an indispensable resource for both research and development (GitHub: https://github.com/fusion-energy).
# '''fusion-energy''' – This is a massive and highly recommended GitHub organization for any neutron physicist working in fusion. It hosts a wide range of projects for fusion neutronics and contains tools like fusion_neutron_utils, fusion_neutronics_workflow, and OpenMC plasma source utilities. These projects enable neutron source generation, Monte Carlo transport simulations, activation and decay analysis, and 3D modeling of fusion device neutronics, making it an indispensable resource for both research and development (GitHub: https://github.com/fusion-energy).
# '''aurora-multiphysics / aurora''' – Integrates neutron transport with multiphysics solvers, allowing simulation of neutron energy deposition, radiation effects, and thermal feedback in complex reactor geometries. (GitHub: https://github.com/aurora-multiphysics/aurora)
# '''aurora-multiphysics / aurora''' – Integrates neutron transport with multiphysics solvers, allowing simulation of neutron energy deposition, radiation effects, and thermal feedback in complex reactor geometries. (GitHub: https://github.com/aurora-multiphysics/aurora)
# '''Fusion-Power-Plant-Framework / tokamak-neutron-source''' – Provides Python tools to generate parametric tokamak neutron sources for Monte Carlo transport codes such as OpenMC and MCNP, based on plasma profiles and fusion reaction distributions. (GitHub: https://github.com/Fusion-Power-Plant-Framework/tokamak-neutron-source)
# '''Fusion-Power-Plant-Framework / tokamak-neutron-source''' – A Python package to create an arbitrary parametric tokamak neutron source for use with Monte Carlo radiation transport codes such as OpenMC and MCNP. It allows specification of plasma profiles (ion density, temperature, equilibrium) and exports source definitions for neutronics simulations. (GitHub: https://github.com/Fusion-Power-Plant-Framework/tokamak-neutron-source)
 


== See Also ==
= See Also =
* [[Nuclear fusion]]
* [[Nuclear fusion]]
* [[TECNO FUS]]
* [[TECNO FUS]]
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* [[Fusion databases]]
* [[Fusion databases]]


== References ==
= External links =
* [https://link.springer.com/book/10.1007/978-981-10-5469-3 Neutronics in Fusion Reactors – Springer Book]
* [https://en.wikipedia.org/wiki/Nuclear_fusion Nuclear Fusion – Wikipedia article]
 
 
= References =
<references>
<references>


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* <ref name="Counters">Link to neutron counters / flux monitor review: Springer, “Neutron Diagnostics for Tokamak Plasma”, 2018. [https://link.springer.com/article/10.1007/s10894-018-0195-9]</ref>
* <ref name="Activation">Activation detectors review: Springer, “Neutron Activation Techniques in Fusion Devices”, 2018. [https://link.springer.com/article/10.1007/s10894-018-0183-0]</ref>
* <ref name="Spectrometers">Spectrometer review: ArXiv, “Proton Recoil Neutron Spectrometers for Tokamak Diagnostics”, 2019. [https://arxiv.org/abs/1902.07633]</ref>
* <ref name="SolidState">Diamond and SiC detectors: Eurofusion, “Diagnostic of Fusion Neutrons on JET Using Diamond Detector”, 2017. [https://scipub.euro-fusion.org/archives/jet-archive/diagnostic-of-fusion-neutrons-on-jet-tokamak-using-diamond-detector/]</ref>
* <ref name="Scintillators">Scintillator detectors: ScienceDirect, “Design of Compact Neutron Detector for Tokamak”, 2025. [https://www.sciencedirect.com/science/article/abs/pii/S0168900225002578]</ref>
* <ref name="Cameras">Neutron cameras and spatial diagnostics: Springer, “Neutron Diagnostics in Tokamaks”, 2018. [https://link.springer.com/article/10.1007/s10894-018-0195-9]</ref>
</ref>
</references>
</references>

Latest revision as of 00:21, 5 February 2026

Neutronics in fusion deals with the behavior and effects of neutrons produced during fusion reactions. In fusion systems, especially in deuterium–tritium reactions, high-energy neutrons (about 14.1 MeV) are generated in large numbers. These neutrons carry most of the fusion energy and interact with the surrounding materials, where their energy is deposited through scattering and nuclear reactions. Neutronics analysis is therefore essential for predicting energy deposition, material damage, radiation shielding requirements, and tritium breeding performance. Understanding neutronics is a key aspect of designing safe, efficient, and sustainable fusion reactors.

Fusion Reactions

The principal nuclear fusion reactions of interest in fusion energy are summarized below, showing their reaction channels and total energy release (Q-value).

D–T Nuclear Fusion Reaction. Source: Neutron Sources, [7]


Reaction Q-value (MeV)
2H+3H4He+n (14.1 MeV) 17.6
2H+2H3He+n (2.45 MeV) 3.27
2H+2H3H+p 4.03
2H+3He4He+p 18.3
3He+3He4He+2p 12.86
p+11B34He 8.68


Neutron Interactions in Fusion Devices

Neutrons are electrically neutral and are not influenced by magnetic fields. As a result, fusion neutrons escape the plasma and interact with reactor materials, producing heat and affecting material behavior. The principal neutron interactions in fusion reactors are summarized below:

Interaction Effect
Radiation Damage Causes atomic displacements and transmutation (He, H), degrading mechanical properties such as strength and ductility
Activation Transforms stable materials into radioactive isotopes, affecting maintenance, waste management, and radiation exposure
Tritium Breeding Neutrons react with lithium to produce tritium [1]:
  • 6Li+n4He+3H(+4.78 MeV)
  • 7Li+n4He+3H+n(2.47 MeV)


Note: Because tritium is extremely rare in nature (half-life ≈ 12.3 years), fusion reactors are initially supplied with tritium from existing stockpiles (primarily from CANDU fission reactors), after which tritium is continuously bred from lithium within the reactor blanket to sustain operation[2].


Neutron Modeling in Plasma Codes

Neutronics simulation plays a fundamental role in the advancement of nuclear fusion by supporting reactor design, safety assessment, and material optimization. The following plasma modeling codes are used to predict fast-ion behavior and fusion-born neutron emission in tokamak and stellarator plasmas, providing neutron source distributions for transport simulations and diagnostic design.

Plasma Code Description and Typical Applications
TRANSP Models plasma conditions and fast-ion dynamics in tokamaks; outputs are used as neutron source terms for transport simulations [3][4]
FIDASIM Simulates fast-ion behavior and predicts fusion-born neutron emission; used to estimate signals for neutron diagnostics like cameras and spectrometers [5]
NUBEAM Module of TRANSP that models fast-ion distributions from neutral beam injection and fusion reactions; computes neutron source profiles [6]
ASCOT Monte Carlo orbit-following codes for fast ions in tokamaks and stellarators; predict localized neutron emission patterns to aid diagnostic design and calibration [7][8]


Neutron Modeling Using Monte Carlo Neutronics Codes

Monte Carlo neutron transport codes are widely used in fusion research to model neutron behavior, material interactions, and diagnostic responses. The table below summarizes the principal neutron-related work performed by each code, together with representative references.

Code Neutron-Related Work in Fusion
MCNP Neutron transport from plasma to reactor components; shielding design; nuclear heating; activation analysis; neutron diagnostics response modeling [9]
Serpent Neutron transport and spectral analysis in fusion blankets; tritium breeding ratio (TBR) calculations; activation and decay heat studies [10]
PHITS Coupled neutron and charged-particle transport; detailed 3D neutronics; radiation damage indicators (DPA, gas production); shielding studies [11]
OpenMC High-fidelity neutron transport in complex 3D fusion geometries; neutron diagnostics scoping; activation analysis; uncertainty and sensitivity studies [12]


Neutron Detectors in Fusion Tokamaks

The progress in neutron detectors for fusion devices has enabled increasingly precise measurements of neutron flux, energy spectra, and spatial emission profiles. Advances in detector technology and modeling now allow researchers to better assess key plasma parameters, including fusion power, ion temperature, and fuel composition.

Method Principle Measures Typical Technology Pros Cons Use in Tokamaks Numerical Tools
Neutron Counters and Flux Monitors[13] Neutrons induce charged particle reactions in gas or fissile material Neutron flux / total yield ³He, BF₃ counters, U-235 / U-238 fission chambers, ionization chambers Robust, wide dynamic range, gamma discrimination Limited energy information, saturation at very high flux Real-time flux monitoring, fusion power measurement MCNP, FLUKA
Activation Detectors[14] Neutrons induce activation in target material Time-integrated neutron fluence Metal foils (Au, In, Al, Nb), delayed neutron activation Simple, high flux tolerant, immune to EM noise Not real-time, requires post-shot analysis Absolute neutron yield calibration, benchmarking MCNP, GEANT4
Neutron Spectrometers (Recoil-Based)[15] Neutrons induce recoil of charged particles Neutron energy spectrum Magnetic Proton Recoil (MPR), proton recoil telescopes, silicon detectors High energy resolution, provides ion temperature and fuel ratio Bulky, sensitive to background, complex shielding Plasma ion temperature, fuel ratio, fast-ion studies MCNP, GEANT4
Solid-State Neutron Detectors[16] Neutrons induce charge in solid-state detector Flux and partial spectral information CVD diamond, SiC detectors Compact, fast response, radiation hard Limited efficiency, calibration complexity ITER-relevant diagnostics, high-flux measurements GEANT4
Scintillator-Based Neutron Detectors[17] Neutrons induce light pulses in scintillator Flux, timing, limited spectral information Liquid or plastic scintillators + PMT/SiPM Fast, allows neutron/gamma discrimination Radiation damage, sensitive to magnetic fields Time-resolved neutron flux, pulse shape discrimination GEANT4
Neutron Cameras[18] Neutrons induce signals in collimated detectors Spatial neutron emissivity (line-integrated) Scintillator or diamond arrays with collimation Spatially resolved plasma information Heavy shielding, complex neutronics Plasma profile mapping, fast-ion studies MCNP, GEANT4


Useful GitHub Repositories for Neutronics in Nuclear Fusion

Several GitHub repositories provide tools and workflows that are highly valuable for neutronics development in fusion research:

  1. fusion-energy – This is a massive and highly recommended GitHub organization for any neutron physicist working in fusion. It hosts a wide range of projects for fusion neutronics and contains tools like fusion_neutron_utils, fusion_neutronics_workflow, and OpenMC plasma source utilities. These projects enable neutron source generation, Monte Carlo transport simulations, activation and decay analysis, and 3D modeling of fusion device neutronics, making it an indispensable resource for both research and development (GitHub: https://github.com/fusion-energy).
  2. aurora-multiphysics / aurora – Integrates neutron transport with multiphysics solvers, allowing simulation of neutron energy deposition, radiation effects, and thermal feedback in complex reactor geometries. (GitHub: https://github.com/aurora-multiphysics/aurora)
  3. Fusion-Power-Plant-Framework / tokamak-neutron-source – A Python package to create an arbitrary parametric tokamak neutron source for use with Monte Carlo radiation transport codes such as OpenMC and MCNP. It allows specification of plasma profiles (ion density, temperature, equilibrium) and exports source definitions for neutronics simulations. (GitHub: https://github.com/Fusion-Power-Plant-Framework/tokamak-neutron-source)

See Also

External links


References

  1. "Breeding blanket," *Wikipedia*, https://en.wikipedia.org/wiki/Breeding_blanket
  2. "Tritium production in CANDU reactors," *Wikipedia*, https://en.wikipedia.org/wiki/Tritium#Production
  3. A. Sperduti et al., “Validation of neutron emission and neutron energy spectrum calculations on a Mega Ampere Spherical Tokamak,” *Plasma Physics and Controlled Fusion*, vol. 63, no. 1, 2021.
  4. “Generation of a plasma neutron source for Monte Carlo neutron transport calculations in the tokamak JET,” *Fusion Engineering and Design*, vol. 136, 2018.
  5. B. Geiger, L. Stagner, W. W. Heidbrink et al., “Progress in modelling fast‑ion D‑alpha spectra and neutral particle analyzer fluxes using FIDASIM,” *Plasma Physics and Controlled Fusion*, 2020.
  6. A. Pankin et al., “The tokamak Monte Carlo fast ion module NUBEAM in the National Transport Code Collaboration library,” *Computer Physics Communications*, vol. 159, 2004.
  7. H. Weisen, P. Sirén, J. Varje & JET Contributors, “Comparison of JET‑C DD neutron rates independently predicted by the ASCOT and TRANSP Monte Carlo heating codes,” *Nuclear Fusion*, vol. 62, 016017, 2022.
  8. J. Kontula et al., “ASCOT simulations of 14 MeV neutron rates in W7‑X: effect of magnetic configuration,” arXiv:2009.02925, 2020.
  9. C. J. Werner (ed.), MCNP User’s Manual – Code Version 6.2, Los Alamos National Laboratory, LA-UR-17-29981.
  10. J. Leppänen et al., The Serpent Monte Carlo Code: Status, Development and Applications in Fusion Neutronics, Annals of Nuclear Energy.
  11. T. Sato et al., Features of Particle and Heavy Ion Transport Code System (PHITS), Journal of Nuclear Science and Technology.
  12. P. K. Romano et al., OpenMC: A State-of-the-Art Monte Carlo Code for Research and Development, Annals of Nuclear Energy.
  13. Link to neutron counters / flux monitor review: Springer, “Neutron Diagnostics for Tokamak Plasma”, 2018. [1]
  14. Activation detectors review: Springer, “Neutron Activation Techniques in Fusion Devices”, 2018. [2]
  15. Spectrometer review: ArXiv, “Proton Recoil Neutron Spectrometers for Tokamak Diagnostics”, 2019. [3]
  16. Diamond and SiC detectors: Eurofusion, “Diagnostic of Fusion Neutrons on JET Using Diamond Detector”, 2017. [4]
  17. Scintillator detectors: ScienceDirect, “Design of Compact Neutron Detector for Tokamak”, 2025. [5]
  18. Neutron cameras and spatial diagnostics: Springer, “Neutron Diagnostics in Tokamaks”, 2018. [6]
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