Comparative study of deuterium retention in irradiated Eurofer and Fe-Cr from a new ion implantation materials facility

A. Hollingsworth; M. Yu Lavrentiev; R. Watkins; A. C. Davies; S. Davies; R. Smith; D. R. Mason; A. Baron-Wiechec; Z. Kollo; J. Hess; I. Jepu; J. Likonen; K. Heinola; K. Mizohata; E. Meslin; M. F. Barthe; A. Widdowson; I. S. Grech; K. Abraham; E. Pender; A. McShee; Y. Martynova; M. Freisinger; A. De Backer

doi:10.1088/1741-4326/ab546e

Comparative study of deuterium retention in irradiated Eurofer and Fe-Cr from a new ion implantation materials facility

A. Hollingsworth^*, M. Yu Lavrentiev, R. Watkins, A. C. Davies, S. Davies, R. Smith, D. R. Mason, A. Baron-Wiechec, Z. Kollo, J. Hess, I. Jepu, J. Likonen, K. Heinola, K. Mizohata, E. Meslin, M. F. Barthe, A. Widdowson, I. S. Grech, K. Abraham, E. PenderA. McShee, Y. Martynova, M. Freisinger, A. De Backer

^*Corresponding author for this work

Materials Science and Engineering

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Abstract

A new facility to study the interaction of hydrogen isotopes with nuclear fusion-relevant first wall materials, and their retention and release, has been produced. The new facility allows for implanting a range of gases into samples, including tritium. An accurate study of isotope effects, such as the isotopic exchange in damaged microstructure, has previously been difficult due to a background signal of light hydrogen. This new capability will allow virtually background free measurements using tritium and deuterium. The design and build of this facility are described and commissioning results are presented. Within the UKAEA-led tritium retention in controlled and evolving microstructure (TRiCEM) project, this facility is used for the comparative study of deuterium retention in self-ion irradiated Eurofer steel and Fe-Cr alloy. Self-ion bombardment with energies of 0.5 MeV is used to mimic the defects created by neutrons in fusion power plants and the created traps are then filled with deuterium in the new facility. Implanted samples are analysed using thermal desorption spectrometry (TDS), secondary ion mass spectrometry (SIMS), and transmission electron microscopy. Results on the total deuterium content as a function of time, TDS spectra and SIMS analysis are presented. A comparison of the results for Eurofer and Fe-Cr revealed several differences. While some of them may be due to experimental details like different time delays between exposure and analysis, others, such as deuterium retention as function of dose, might be genuine and require further studies.

Original language	English
Article number	016024
Journal	Nuclear Fusion
Volume	60
Issue number	1
DOIs	https://doi.org/10.1088/1741-4326/ab546e
State	Published - 2020

Keywords

Eurofer
deuterium
implanting
iron-chromium
retention
tritium

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10.1088/1741-4326/ab546e

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Hollingsworth, A., Lavrentiev, M. Y., Watkins, R., Davies, A. C., Davies, S., Smith, R., Mason, D. R., Baron-Wiechec, A., Kollo, Z., Hess, J., Jepu, I., Likonen, J., Heinola, K., Mizohata, K., Meslin, E., Barthe, M. F., Widdowson, A., Grech, I. S., Abraham, K., ... De Backer, A. (2020). Comparative study of deuterium retention in irradiated Eurofer and Fe-Cr from a new ion implantation materials facility. Nuclear Fusion, 60(1), Article 016024. https://doi.org/10.1088/1741-4326/ab546e

@article{17ace0cfa69f436e8d36e28f08ff7a92,

title = "Comparative study of deuterium retention in irradiated Eurofer and Fe-Cr from a new ion implantation materials facility",

abstract = "A new facility to study the interaction of hydrogen isotopes with nuclear fusion-relevant first wall materials, and their retention and release, has been produced. The new facility allows for implanting a range of gases into samples, including tritium. An accurate study of isotope effects, such as the isotopic exchange in damaged microstructure, has previously been difficult due to a background signal of light hydrogen. This new capability will allow virtually background free measurements using tritium and deuterium. The design and build of this facility are described and commissioning results are presented. Within the UKAEA-led tritium retention in controlled and evolving microstructure (TRiCEM) project, this facility is used for the comparative study of deuterium retention in self-ion irradiated Eurofer steel and Fe-Cr alloy. Self-ion bombardment with energies of 0.5 MeV is used to mimic the defects created by neutrons in fusion power plants and the created traps are then filled with deuterium in the new facility. Implanted samples are analysed using thermal desorption spectrometry (TDS), secondary ion mass spectrometry (SIMS), and transmission electron microscopy. Results on the total deuterium content as a function of time, TDS spectra and SIMS analysis are presented. A comparison of the results for Eurofer and Fe-Cr revealed several differences. While some of them may be due to experimental details like different time delays between exposure and analysis, others, such as deuterium retention as function of dose, might be genuine and require further studies.",

keywords = "Eurofer, deuterium, implanting, iron-chromium, retention, tritium",

author = "A. Hollingsworth and Lavrentiev, {M. Yu} and R. Watkins and Davies, {A. C.} and S. Davies and R. Smith and Mason, {D. R.} and A. Baron-Wiechec and Z. Kollo and J. Hess and I. Jepu and J. Likonen and K. Heinola and K. Mizohata and E. Meslin and Barthe, {M. F.} and A. Widdowson and Grech, {I. S.} and K. Abraham and E. Pender and A. McShee and Y. Martynova and M. Freisinger and {De Backer}, A.",

note = "Publisher Copyright: {\textcopyright} EURATOM 2019.",

year = "2020",

doi = "10.1088/1741-4326/ab546e",

language = "英语",

volume = "60",

journal = "Nuclear Fusion",

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Hollingsworth, A, Lavrentiev, MY, Watkins, R, Davies, AC, Davies, S, Smith, R, Mason, DR, Baron-Wiechec, A, Kollo, Z, Hess, J, Jepu, I, Likonen, J, Heinola, K, Mizohata, K, Meslin, E, Barthe, MF, Widdowson, A, Grech, IS, Abraham, K, Pender, E, McShee, A, Martynova, Y, Freisinger, M & De Backer, A 2020, 'Comparative study of deuterium retention in irradiated Eurofer and Fe-Cr from a new ion implantation materials facility', Nuclear Fusion, vol. 60, no. 1, 016024. https://doi.org/10.1088/1741-4326/ab546e

TY - JOUR

T1 - Comparative study of deuterium retention in irradiated Eurofer and Fe-Cr from a new ion implantation materials facility

AU - Hollingsworth, A.

AU - Lavrentiev, M. Yu

AU - Watkins, R.

AU - Davies, A. C.

AU - Davies, S.

AU - Smith, R.

AU - Mason, D. R.

AU - Baron-Wiechec, A.

AU - Kollo, Z.

AU - Hess, J.

AU - Jepu, I.

AU - Likonen, J.

AU - Heinola, K.

AU - Mizohata, K.

AU - Meslin, E.

AU - Barthe, M. F.

AU - Widdowson, A.

AU - Grech, I. S.

AU - Abraham, K.

AU - Pender, E.

AU - McShee, A.

AU - Martynova, Y.

AU - Freisinger, M.

AU - De Backer, A.

PY - 2020

Y1 - 2020

N2 - A new facility to study the interaction of hydrogen isotopes with nuclear fusion-relevant first wall materials, and their retention and release, has been produced. The new facility allows for implanting a range of gases into samples, including tritium. An accurate study of isotope effects, such as the isotopic exchange in damaged microstructure, has previously been difficult due to a background signal of light hydrogen. This new capability will allow virtually background free measurements using tritium and deuterium. The design and build of this facility are described and commissioning results are presented. Within the UKAEA-led tritium retention in controlled and evolving microstructure (TRiCEM) project, this facility is used for the comparative study of deuterium retention in self-ion irradiated Eurofer steel and Fe-Cr alloy. Self-ion bombardment with energies of 0.5 MeV is used to mimic the defects created by neutrons in fusion power plants and the created traps are then filled with deuterium in the new facility. Implanted samples are analysed using thermal desorption spectrometry (TDS), secondary ion mass spectrometry (SIMS), and transmission electron microscopy. Results on the total deuterium content as a function of time, TDS spectra and SIMS analysis are presented. A comparison of the results for Eurofer and Fe-Cr revealed several differences. While some of them may be due to experimental details like different time delays between exposure and analysis, others, such as deuterium retention as function of dose, might be genuine and require further studies.

AB - A new facility to study the interaction of hydrogen isotopes with nuclear fusion-relevant first wall materials, and their retention and release, has been produced. The new facility allows for implanting a range of gases into samples, including tritium. An accurate study of isotope effects, such as the isotopic exchange in damaged microstructure, has previously been difficult due to a background signal of light hydrogen. This new capability will allow virtually background free measurements using tritium and deuterium. The design and build of this facility are described and commissioning results are presented. Within the UKAEA-led tritium retention in controlled and evolving microstructure (TRiCEM) project, this facility is used for the comparative study of deuterium retention in self-ion irradiated Eurofer steel and Fe-Cr alloy. Self-ion bombardment with energies of 0.5 MeV is used to mimic the defects created by neutrons in fusion power plants and the created traps are then filled with deuterium in the new facility. Implanted samples are analysed using thermal desorption spectrometry (TDS), secondary ion mass spectrometry (SIMS), and transmission electron microscopy. Results on the total deuterium content as a function of time, TDS spectra and SIMS analysis are presented. A comparison of the results for Eurofer and Fe-Cr revealed several differences. While some of them may be due to experimental details like different time delays between exposure and analysis, others, such as deuterium retention as function of dose, might be genuine and require further studies.

KW - Eurofer

KW - deuterium

KW - implanting

KW - iron-chromium

KW - retention

KW - tritium

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U2 - 10.1088/1741-4326/ab546e

DO - 10.1088/1741-4326/ab546e

M3 - 文章

AN - SCOPUS:85081330912

SN - 0029-5515

VL - 60

JO - Nuclear Fusion

JF - Nuclear Fusion

IS - 1

M1 - 016024

ER -

Comparative study of deuterium retention in irradiated Eurofer and Fe-Cr from a new ion implantation materials facility

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