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Tungsten fuzz: Deposition effects and influence to fusion devices

Shin Kajita / Naoaki Yoshida / Noriyasu Ohno

Helium (He) plasma irradiation to tungsten leads to formation of He bubbles and fiberform nanostructures called fuzz on the surface. Although the fuzz growth condition and growth rate have been well investigated, deposition of W together with He ions can change the He effect significantly. For example, the deposition leads to large-scale structures such as nano-tendril bundles and mm-thick large-scale fiberform nanostructures. In this review, current understanding of deposition effects on He irradiation are summarized, and the influence to fusion devices is discussed mainly from the view point of arcing.

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Tungsten fuzz: Deposition effects and influence to fusion devices

Shin Kajita / Naoaki Yoshida / Noriyasu Ohno

Helium (He) plasma irradiation to tungsten leads to formation of He bubbles and fiberform nanostructures called fuzz on the surface. Although the fuzz growth condition and growth rate have been well investigated, deposition of W together with He ions can change the He effect significantly. For example, the deposition leads to large-scale structures such as nano-tendril bundles and mm-thick large-scale fiberform nanostructures. In this review, current understanding of deposition effects on He irradiation are summarized, and the influence to fusion devices is discussed mainly from the view point of arcing.

Tungsten fuzz: Deposition effects and influence to fusion devices

Shin Kajita / Naoaki Yoshida / Noriyasu Ohno

Helium (He) plasma irradiation to tungsten leads to formation of He bubbles and fiberform nanostructures called fuzz on the surface. Although the fuzz growth condition and growth rate have been well investigated, deposition of W together with He ions can change the He effect significantly. For example, the deposition leads to large-scale structures such as nano-tendril bundles and mm-thick large-scale fiberform nanostructures. In this review, current understanding of deposition effects on He irradiation are summarized, and the influence to fusion devices is discussed mainly from the view point of arcing.

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Title:

Tungsten fuzz: Deposition effects and influence to fusion devices

Contributors:

Shin Kajita (author) / Naoaki Yoshida (author) / Noriyasu Ohno (author)

Published in:

Nuclear Materials and Energy, Vol 25, Iss , Pp 100828- (2020)

Publication date:

2020

ISSN:

DOI:

https://doi.org/10.1016/j.nme.2020.100828

Type of media:

Article (Journal)

Type of material:

Electronic Resource

Language:

Unknown

Keywords:

Helium , Tungsten , Nanostructure , Deposition , Arcing , Nuclear fusion , Nuclear engineering. Atomic power , TK9001-9401

Metadata by DOAJ is licensed under CC BY-SA 1.0

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