Bibliography

Bibliography#

[1]

Rémi Delaporte-Mathurin, Etienne A. Hodille, Jonathan Mougenot, Yann Charles, and Christian Grisolia. Finite element analysis of hydrogen retention in ITER plasma facing components using FESTIM. Nuclear Materials and Energy, 21:100709, December 2019. URL: https://linkinghub.elsevier.com/retrieve/pii/S2352179119300547 (visited on 2023-02-10), doi:10.1016/j.nme.2019.100709.

[2]

Martin Alnæs, Jan Blechta, Johan Hake, August Johansson, Benjamin Kehlet, Anders Logg, Chris Richardson, Johannes Ring, Marie E. Rognes, and Garth N. Wells. The FEniCS Project Version 1.5. Archive of Numerical Software, December 2015. URL: https://journals.ub.uni-heidelberg.de/index.php/ans/article/view/20553 (visited on 2019-10-07), doi:10.11588/ans.2015.100.20553.

[3]

James Ambrosek. Verification and Validation of TMAP7. Technical Report INEEL/EXT-04-01657, Idaho National Lab. (INL), Idaho Falls, ID (United States), December 2008. URL: https://www.osti.gov/biblio/952009 (visited on 2024-03-08), doi:10.2172/952009.

[4]

E. A. Hodille, X. Bonnin, R. Bisson, T. Angot, C. S. Becquart, J. M. Layet, and C. Grisolia. Macroscopic rate equation modeling of trapping/detrapping of hydrogen isotopes in tungsten materials. Journal of Nuclear Materials, 467:424–431, December 2015. URL: http://www.sciencedirect.com/science/article/pii/S0022311515300660 (visited on 2019-10-07), doi:10.1016/j.jnucmat.2015.06.041.

[5]

R. Arredondo, K. Schmid, F. Subba, and G. A. Spagnuolo. Preliminary estimates of tritium permeation and retention in the first wall of DEMO due to ion bombardment. Nuclear Materials and Energy, 28:101039, September 2021. URL: https://www.sciencedirect.com/science/article/pii/S2352179121001125 (visited on 2021-11-10), doi:10.1016/j.nme.2021.101039.

[6]

D. Matveev, M. Zlobinski, G. De Temmerman, B. Unterberg, and C. Linsmeier. CRDS modelling of deuterium release from co-deposited beryllium layers in temperature programmed and laser induced desorption experiments. Physica Scripta, 2020(T171):014053, March 2020. Publisher: IOP Publishing. URL: https://dx.doi.org/10.1088/1402-4896/ab5569 (visited on 2023-09-14), doi:10.1088/1402-4896/ab5569.

[7]

Alexander Lindsay. TMAP8. 2021. Language: en. URL: https://www.osti.gov/doecode/biblio/50762 (visited on 2023-09-14), doi:10.11578/DC.20210205.2.

[8]

stephen-dixon. Aurora-multiphysics/achlys: Patch for latest moose version. February 2023. URL: https://zenodo.org/record/7662692 (visited on 2023-09-14), doi:10.5281/zenodo.7662692.

[9]

Christopher J. Roy and William L. Oberkampf. Exact solutions. In Verification and Validation in Scientific Computing, pages 208–248. Cambridge University Press, Cambridge, 2010. URL: https://www.cambridge.org/core/books/verification-and-validation-in-scientific-computing/exact-solutions/DFB030CD8A8334FA13DF3B2A627964E4 (visited on 2023-10-12), doi:10.1017/CBO9780511760396.009.

[10]

R.A. Anderl, D.F. Holland, D.A. Struttmann, G.R. Longhurst, and B.J. Merrill. Tritium permeation in stainless steel-structures exposed to plasma ions. IEEE Service Center, United States, 1986. INIS Reference Number: 18011522.

[11]

G. R. Longhurst, S. L. Harms, E. S. Marwil, and B. G. Miller. Verification and validation of TMAP4. Technical Report EGG-FSP-10347, EG and G Idaho, Inc., Idaho Falls, ID (United States), July 1992. URL: https://www.osti.gov/biblio/10174725 (visited on 2024-03-08), doi:10.2172/10174725.

[12]

O. V Ogorodnikova, J Roth, and M Mayer. Deuterium retention in tungsten in dependence of the surface conditions. Journal of Nuclear Materials, 313-316:469–477, March 2003. URL: https://www.sciencedirect.com/science/article/pii/S0022311502013752 (visited on 2024-06-04), doi:10.1016/S0022-3115(02)01375-2.

[13]

R. Frauenfelder. Permeation of Hydrogen through Tungsten and Molybdenum. The Journal of Chemical Physics, 48(9):3955–3965, May 1968. URL: https://doi.org/10.1063/1.1669720 (visited on 2024-06-13), doi:10.1063/1.1669720.

[14]

James Dark, Rémi Delaporte-Mathurin, Thomas Schwarz-Selinger, Etienne A. Hodille, Jonathan Mougenot, Yann Charles, and Christian Grisolia. Modelling neutron damage effects on tritium transport in tungsten. Nuclear Fusion, 64(8):086026, August 2024. URL: https://iopscience.iop.org/article/10.1088/1741-4326/ad56a0 (visited on 2024-06-29), doi:10.1088/1741-4326/ad56a0.

[15]

G Holzner, T Schwarz-Selinger, T Dürbeck, and U von Toussaint. Solute diffusion of hydrogen isotopes in tungsten—a gas loading experiment. Physica Scripta, 2020(T171):014034, mar 2020. URL: https://dx.doi.org/10.1088/1402-4896/ab4b42, doi:10.1088/1402-4896/ab4b42.

[16]

James Dark. J-Dark-PhD/Modelling_neutron_damage_effects_in_tungsten: Final submission. April 2024. URL: https://zenodo.org/records/11085134 (visited on 2024-06-29), doi:10.5281/zenodo.11085134.

[17]

M. J. Baldwin, T. Schwarz-Selinger, and R. P. Doerner. Experimental study and modelling of deuterium thermal release from Be–D co-deposited layers. Nuclear Fusion, 54(7):073005, April 2014. Publisher: IOP Publishing. URL: https://dx.doi.org/10.1088/0029-5515/54/7/073005 (visited on 2024-06-17), doi:10.1088/0029-5515/54/7/073005.

[18]

Y. Hirooka, M. Miyake, and T. Sano. A study of hydrogen absorption and desorption by titanium. Journal of Nuclear Materials, 96:227–232, 2 1981. doi:10.1016/0022-3115(81)90566-3.

[19]

Yuta Shimohata, Yoshiki Hamamoto, Kengo Nishi, and Katsuaki Tanabe. Improved kinetic model of hydrogen absorption and desorption in titanium with subsurface transport. Fusion Engineering and Design, 173:112833, 12 2021. doi:10.1016/J.FUSENGDES.2021.112833.

[20]

G W Wille and J W Davis. Hydrogen in titanium alloys. 4 1981. doi:10.2172/6420120.

[21]

Vladimir Kulagin, Rémi Delaporte-Mathurin, Etienne A. Hodille, and Mikhail Zibrov. Kinetic surface model in festim: verification and validation. International Journal of Hydrogen Energy, 110:90–100, 3 2024. doi:10.1016/J.IJHYDENE.2025.02.128.

[22]

A. Dunand, M. Minissale, J. B. Faure, L. Gallais, T. Angot, and R. Bisson. Surface oxygen versus native oxide on tungsten: contrasting effects on deuterium retention and release. Nuclear Fusion, 62:054002, 3 2022. doi:10.1088/1741-4326/AC583A.

[23]

E. Hodille, B. Pavec, J. Denis, A. Dunand, Y. Ferro, M. Minissale, T. Angot, C. Grisolia, and R. Bisson. Deuterium uptake, desorption and sputtering from w(110) surface covered with oxygen. Nuclear Fusion, 64:046022, 3 2024. doi:10.1088/1741-4326/AD2A29.

[24]

N. Fernandez, Y. Ferro, and D. Kato. Hydrogen diffusion and vacancies formation in tungsten: density functional theory calculations and statistical models. Acta Materialia, 94:307–318, 8 2015. doi:10.1016/J.ACTAMAT.2015.04.052.

[25]

S. Markelj, A. Založnik, T. Schwarz-Selinger, O. V. Ogorodnikova, P. Vavpetič, P. Pelicon, and I. Čadež. In situ nra study of hydrogen isotope exchange in self-ion damaged tungsten exposed to neutral atoms. Journal of Nuclear Materials, 469:133–144, 2 2016. doi:10.1016/J.JNUCMAT.2015.11.039.

[26]

E. A. Hodille, A. Založnik, S. Markelj, T. Schwarz-Selinger, C. S. Becquart, R. Bisson, and C. Grisolia. Simulations of atomic deuterium exposure in self-damaged tungsten. Nuclear Fusion, 57:056002, 3 2017. doi:10.1088/1741-4326/AA5AA5.

[27]

K. Schmid, T. Schwarz-Selinger, and R. Arredondo. Influence of hydrogen isotopes on displacement damage formation in eurofer. Nuclear Materials and Energy, 34:101341, 3 2023. doi:10.1016/J.NME.2022.101341.

[28]

K. Schmid, T. Schwarz-Selinger, and A. Theodorou. Modeling intrinsic- and displacement-damage-driven retention in eurofer. Nuclear Materials and Energy, 36:101494, 9 2023. doi:10.1016/J.NME.2023.101494.

[29]

A. Aiello, I. Ricapito, G. Benamati, and R. Valentini. Hydrogen isotopes permeability in eurofer 97 martensitic steel. Fusion Science and Technology, 41:872–876, 2002. doi:10.13182/FST41-872.