TY - JOUR
T1 - Demonstration of Helide formation for fusion structural materials as natural lattice sinks for helium
AU - Kim, So Yeon
AU - Kavak, Sina
AU - Bayrak, Kübra Gürcan
AU - Sun, Cheng
AU - Xu, Haowei
AU - Lee, Myeong Jun
AU - Chen, Di
AU - Zhang, Yong
AU - Tekoğlu, Emre
AU - Ağaoğulları, Duygu
AU - Ayas, Erhan
AU - Park, Eun Soo
AU - Li, Ju
N1 - Publisher Copyright:
© 2024
PY - 2024/3/1
Y1 - 2024/3/1
N2 - Fusion power holds promise as an ultimate energy source. However, achieving true sustainability in fusion energy requires addressing the embrittlement of polycrystalline materials in fusion reactors caused by helium, which leads to premature failure, often within a year. Here we experimentally demonstrate that nanodispersoids with constitutional vacancy-like atomic-scale free volume can securely store helium, not only at the matrix-dispersoid interface but also within their bulk lattices, which suggests their effectiveness in delaying critical helium damage of the polycrystalline matrix. The selected model nano-heterophase, fayalite Fe2SiO4, possesses moderately strong lattice sinks for helium while undergoing lattice distortions upon helium absorption. These distortions cause observable changes in peak intensities of X-ray diffraction (XRD) patterns, distinct from changes resulting from other factors like radiation damage. By comparing grazing incidence XRD patterns with ab initio computed patterns, we show that such nano-heterophases can store up to ∼10 at% helium within their bulk lattice, forming a “helide compound.” Incorporating just 1 vol% of Fe2SiO4 reduces helium bubble size and number density by >20 % and >50 %, respectively. These findings suggest that 1–2 vol% of appropriate nano-heterophases can accommodate a few thousand appm of bulk helium, expected to be generated over a 10-year operational period.
AB - Fusion power holds promise as an ultimate energy source. However, achieving true sustainability in fusion energy requires addressing the embrittlement of polycrystalline materials in fusion reactors caused by helium, which leads to premature failure, often within a year. Here we experimentally demonstrate that nanodispersoids with constitutional vacancy-like atomic-scale free volume can securely store helium, not only at the matrix-dispersoid interface but also within their bulk lattices, which suggests their effectiveness in delaying critical helium damage of the polycrystalline matrix. The selected model nano-heterophase, fayalite Fe2SiO4, possesses moderately strong lattice sinks for helium while undergoing lattice distortions upon helium absorption. These distortions cause observable changes in peak intensities of X-ray diffraction (XRD) patterns, distinct from changes resulting from other factors like radiation damage. By comparing grazing incidence XRD patterns with ab initio computed patterns, we show that such nano-heterophases can store up to ∼10 at% helium within their bulk lattice, forming a “helide compound.” Incorporating just 1 vol% of Fe2SiO4 reduces helium bubble size and number density by >20 % and >50 %, respectively. These findings suggest that 1–2 vol% of appropriate nano-heterophases can accommodate a few thousand appm of bulk helium, expected to be generated over a 10-year operational period.
KW - Ab initio calculations
KW - Grain boundary embrittlement
KW - Grazing incidence XRD
KW - Helium
KW - Irradiation
UR - http://www.scopus.com/inward/record.url?scp=85183319709&partnerID=8YFLogxK
U2 - 10.1016/j.actamat.2024.119654
DO - 10.1016/j.actamat.2024.119654
M3 - Article
AN - SCOPUS:85183319709
SN - 1359-6454
VL - 266
JO - Acta Materialia
JF - Acta Materialia
M1 - 119654
ER -