Novel nano-crystalline Er2O3 hydrogen isotopes permeation barriers

Novel nano-crystalline Er2O3 hydrogen isotopes permeation barriers

Hydrogen Isotopes permeation barriers (HIPB) are used to reduce hydrogen isotopes permeation and leakage in the fields such as thermonuclear fusion energy, hydrogen energy, petroleum industry and vacuum solar receiver. In this study, nano-crystalline Er2O3 HIPB with about 5–10nm grain size were made...

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Bibliographic Details
Published in:Journal of the European Ceramic Society Vol. 37; no. 1; pp. 249 - 254
Main Authors: Li, Qun, Wang, Jie, Xiang, Qing-yun, Yan, Kai, Tang, Tao, Rao, Yong-Chu, Cao, Jiang-Li
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-01-2017
Subjects:
D-PRFD-prf
Deuterium permeation
Er2O3 coatings
Nano-crystalline
Thermonuclear fusion
Er2O3 coatings
Deuterium permeation
Thermonuclear fusion
D-PRFD-prf
Nano-crystalline
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Summary:Hydrogen Isotopes permeation barriers (HIPB) are used to reduce hydrogen isotopes permeation and leakage in the fields such as thermonuclear fusion energy, hydrogen energy, petroleum industry and vacuum solar receiver. In this study, nano-crystalline Er2O3 HIPB with about 5–10nm grain size were made by sol-gel method. Their performances, including deuterium-permeation reduction factor (D-PRF), micro-structure, mechanical property and electrical property were reported. The D-PRF of 0.2μm nano-crystalline Er2O3 HIPB reached 300 at 700°C and did not deteriorate after 128h deuterium permeation. The bonding strength and the nano-hardness steadily remained about 13N and 10GPa after 128h deuterium permeation at 700°C, respectively. The morphology and micro-structures of the nano-crystalline Er2O3 HIPB showed no measurable changes after 128h deuterium permeation, which ensured the stable D-PRF and mechanical properties. However, the electrical resistivity of the nano-crystalline Er2O3 HIPB decreased after deuterium permeation at 700°C. The electrical resistivity decreased from 9×109Ωcm by over three orders of magnitude and then tended to be stable, which might be attributed to oxygen loss or deuterium invasion.
ISSN:0955-2219
1873-619X
DOI:10.1016/j.jeurceramsoc.2016.07.035