First evidence of helium in the tungsten divertor of the WEST tokamak

M. Diez; C. Martin; Antti Hakola; A. Huart; Y. Corre; J. Gaspar; Z. Siketić; G. Giacometti; T. Neisius; M. Cabié; Q. Tichit; Tomi Vuoriheimo; A. Benmoumen; E. Tsitrone; I.Bogdanovic Radovic; WEST Team

doi:10.1016/j.nme.2026.102135

First evidence of helium in the tungsten divertor of the WEST tokamak

M. Diez
, C. Martin
, Antti Hakola
, A. Huart
, Y. Corre
, J. Gaspar
, Z. Siketić
, G. Giacometti
, T. Neisius
, M. Cabié
, Q. Tichit
, Tomi Vuoriheimo
, A. Benmoumen
, E. Tsitrone
, I.Bogdanovic Radovic^*
, WEST Team

^*Corresponding author for this work

BA4511 Fusion energy

Commissariat a l'Energie Atomique et aux Energies Alternatives (CEA)
Aix-Marseille Université
Ruđer Bošković Institute (IRB)
VTT (former employee or external)

Research output: Contribution to journal › Article › Scientific › peer-review

Abstract

ITER will operate with plasma-facing materials made of tungsten, a material whose surface morphology changes when exposed to helium plasmas at sufficient high energy, fluence and surface temperature. To predict any potential changes to tungsten in future fusion reactors, a dedicated helium campaign was carried out in WEST in 2019. The plasma scenarios developed during this campaign were aimed in particular at forming tungsten fuzz on the surface of tungsten-coated graphite divertor components. A large-scale post-mortem study reveals for the first time the radial and toroidal distributions of helium content in the components determined post-mortem by ion beam analysis at the divertor scale. The results show that helium is mainly found in tungsten at the strike point areas, with concentrations reaching up to 10 at.% near the surface to an analysed depth of 0.2 µm. This is accompanied by the presence of nanobubbles in the microstructure up to 10 nm below the surface observed by electron microscopy. The same observation was made in bulk tungsten ITER-like PFUs. However, no tungsten fuzz was observed.

Original language	English
Article number	102135
Journal	Nuclear Materials and Energy
Volume	47
DOIs	https://doi.org/10.1016/j.nme.2026.102135
Publication status	Published - Jun 2026
MoE publication type	A1 Journal article-refereed

Funding

his work has been carried out within the framework of the EUROfusion Consortium, funded by the European Union via the Euratom Research and Training Programme (Grant Agreement No 101052200 — EUROfusion).

Keywords

Helium
Implantation
Nanobubbles
Tungsten
WEST tokamak

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Cite this

Diez, M., Martin, C., Hakola, A., Huart, A., Corre, Y., Gaspar, J., Siketić, Z., Giacometti, G., Neisius, T., Cabié, M., Tichit, Q., Vuoriheimo, T., Benmoumen, A., Tsitrone, E., Radovic, I. B., & WEST Team (2026). First evidence of helium in the tungsten divertor of the WEST tokamak. Nuclear Materials and Energy, 47, Article 102135. https://doi.org/10.1016/j.nme.2026.102135

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title = "First evidence of helium in the tungsten divertor of the WEST tokamak",

abstract = "ITER will operate with plasma-facing materials made of tungsten, a material whose surface morphology changes when exposed to helium plasmas at sufficient high energy, fluence and surface temperature. To predict any potential changes to tungsten in future fusion reactors, a dedicated helium campaign was carried out in WEST in 2019. The plasma scenarios developed during this campaign were aimed in particular at forming tungsten fuzz on the surface of tungsten-coated graphite divertor components. A large-scale post-mortem study reveals for the first time the radial and toroidal distributions of helium content in the components determined post-mortem by ion beam analysis at the divertor scale. The results show that helium is mainly found in tungsten at the strike point areas, with concentrations reaching up to 10 at.\% near the surface to an analysed depth of 0.2 µm. This is accompanied by the presence of nanobubbles in the microstructure up to 10 nm below the surface observed by electron microscopy. The same observation was made in bulk tungsten ITER-like PFUs. However, no tungsten fuzz was observed.",

keywords = "Helium, Implantation, Nanobubbles, Tungsten, WEST tokamak",

author = "M. Diez and C. Martin and Antti Hakola and A. Huart and Y. Corre and J. Gaspar and Z. Siketi{\'c} and G. Giacometti and T. Neisius and M. Cabi{\'e} and Q. Tichit and Tomi Vuoriheimo and A. Benmoumen and E. Tsitrone and I.Bogdanovic Radovic and \{WEST Team\}",

year = "2026",

month = jun,

doi = "10.1016/j.nme.2026.102135",

language = "English",

volume = "47",

journal = "Nuclear Materials and Energy",

issn = "2352-1791",

publisher = "Elsevier",

}

TY - JOUR

T1 - First evidence of helium in the tungsten divertor of the WEST tokamak

AU - Diez, M.

AU - Martin, C.

AU - Hakola, Antti

AU - Huart, A.

AU - Corre, Y.

AU - Gaspar, J.

AU - Siketić, Z.

AU - Giacometti, G.

AU - Neisius, T.

AU - Cabié, M.

AU - Tichit, Q.

AU - Vuoriheimo, Tomi

AU - Benmoumen, A.

AU - Tsitrone, E.

AU - Radovic, I.Bogdanovic

AU - WEST Team

PY - 2026/6

Y1 - 2026/6

N2 - ITER will operate with plasma-facing materials made of tungsten, a material whose surface morphology changes when exposed to helium plasmas at sufficient high energy, fluence and surface temperature. To predict any potential changes to tungsten in future fusion reactors, a dedicated helium campaign was carried out in WEST in 2019. The plasma scenarios developed during this campaign were aimed in particular at forming tungsten fuzz on the surface of tungsten-coated graphite divertor components. A large-scale post-mortem study reveals for the first time the radial and toroidal distributions of helium content in the components determined post-mortem by ion beam analysis at the divertor scale. The results show that helium is mainly found in tungsten at the strike point areas, with concentrations reaching up to 10 at.% near the surface to an analysed depth of 0.2 µm. This is accompanied by the presence of nanobubbles in the microstructure up to 10 nm below the surface observed by electron microscopy. The same observation was made in bulk tungsten ITER-like PFUs. However, no tungsten fuzz was observed.

AB - ITER will operate with plasma-facing materials made of tungsten, a material whose surface morphology changes when exposed to helium plasmas at sufficient high energy, fluence and surface temperature. To predict any potential changes to tungsten in future fusion reactors, a dedicated helium campaign was carried out in WEST in 2019. The plasma scenarios developed during this campaign were aimed in particular at forming tungsten fuzz on the surface of tungsten-coated graphite divertor components. A large-scale post-mortem study reveals for the first time the radial and toroidal distributions of helium content in the components determined post-mortem by ion beam analysis at the divertor scale. The results show that helium is mainly found in tungsten at the strike point areas, with concentrations reaching up to 10 at.% near the surface to an analysed depth of 0.2 µm. This is accompanied by the presence of nanobubbles in the microstructure up to 10 nm below the surface observed by electron microscopy. The same observation was made in bulk tungsten ITER-like PFUs. However, no tungsten fuzz was observed.

KW - Helium

KW - Implantation

KW - Nanobubbles

KW - Tungsten

KW - WEST tokamak

UR - https://www.scopus.com/pages/publications/105037430992

U2 - 10.1016/j.nme.2026.102135

DO - 10.1016/j.nme.2026.102135

M3 - Article

SN - 2352-1791

VL - 47

JO - Nuclear Materials and Energy

JF - Nuclear Materials and Energy

M1 - 102135

ER -

First evidence of helium in the tungsten divertor of the WEST tokamak

Abstract

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Keywords

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