Atomic and ionic hydrogen flux probe for quantitative in-situ monitoring of hydrogen recycling

被引：0

作者：

Kuzmin, A. ^{[1
]}

Miura, K. ^{[2
]}

Kobayashi, M. ^{[2
]}

Hanada, K. ^{[3
]}

Fujii, K. ^{[1
,4
]}

Shikama, T. ^{[1
]}

Hasuo, M. ^{[1
]}

Zushi, H. ^{[3
]}

机构：

[1] Kyoto Univ, Kyotodaigaku Katsura Nishikyo ku, Kyoto, Kyoto 6158540, Japan

[2] Natl Inst Fus Sci, 322-6 Oroshi cho, Toki, Gifu 5095292, Japan

[3] Kyushu Univ, Res Inst Appl Mech, 6-1 Kasugakoen Kasuga, Fukuoka 8168580, Japan

[4] Oak Ridge Natl Lab, Oak Ridge, TN 37831 USA

来源：

FUSION ENGINEERING AND DESIGN | 2023年 / 189卷

关键词：

Hydrogen; Atomic hydrogen; Steady state tokamak operation; PdCu; Permeation; MOLECULAR-HYDROGEN; DRIVEN PERMEATION; PLASMA; DIAGNOSTICS;

D O I：

10.1016/j.fusengdes.2023.113462

中图分类号：

TL [原子能技术]; O571 [原子核物理学];

学科分类号：

0827 ; 082701 ;

摘要：

A new combination diagnostic as a hydrogen recycling monitor in harsh conditions is proposed. Combining permeation membrane probe with a Langmuir probe provides a possibility to measure both atomic and ionic hydrogen fluxes to plasma facing components. A brief overview of permeation probes is given. The range of measurable H fluxes is from 10(16) to more than 10(20) H m(-2)s(-1). Time response of the permeation probe is similar to 0.1-0.5 s. A method to address disadvantages of permeation probes is proposed. This includes an introduction of a preparation chamber for Ar-plasma cleaning of the membrane and absolute calibration with a visible spectroscopy. The hydrogen recombination coefficient, evaluated in such calibration, is k(u) = 5.9 x 10(-30) m(4)s(-1), which agrees well with previous research.

引用

页数：5

共 50 条

[21] Removal of Tin from Extreme Ultraviolet Collector Optics by In-Situ Hydrogen Plasma Etching
Daniel T. Elg
Gianluca A. Panici
Sumeng Liu
Gregory Girolami
Shailendra N. Srivastava
David N. Ruzic
Plasma Chemistry and Plasma Processing, 2018, 38 : 223 - 245
[22] Quantification of Hydrogen Flux from Atmospheric Corrosion of Steel Using the Scanning Kelvin Probe Technique
Vucko, Flavien
Helbert, Varvara Shubina
Nazarov, Andrei
METALS, 2023, 13 (08)
[23] In-situ visualization of hydrogen atom distribution at micro-indentation in a carbon steel by scanning Kelvin probe force microscopy
Li, Yuan
Cheng, Yufeng Frank
CORROSION REVIEWS, 2023, 41 (04) : 473 - 483
[24] Identification and quantification of electron-generated atomic hydrogen through in-situ electron spin resonance and density functional theory
Yi, Genping
Wang, Bo
Lu, Sen
Zhang, Liying
Liu, Wenzong
Chen, Zheyu
Yang, Liming
Luo, Xubiao
Wang, Ai-Jie
CHEMICAL ENGINEERING JOURNAL, 2024, 483
[25] Atomic-resolution environmental TEM for quantitative in-situ microscopy in materials science
Takeda, Seiji
Yoshida, Hideto
MICROSCOPY, 2013, 62 (01) : 193 - 203
[26] Hydrogen Effects on Fracture Resistances of Bulk Cementite Evaluated by in-situ Microbending Test during Cathodic Hydrogen Charging
Tomatsu, Kota
Sasaki, Masahiro
Aoki, Takahiro
Omura, Tomohiko
ISIJ INTERNATIONAL, 2024, 64 (04) : 696 - 705
[27] In-situ neutron radiography investigations of hydrogen diffusion and absorption in zirconium alloys
Grosse, M.
van den Berg, M.
Goulet, C.
Lehmann, E.
Schillinger, B.
NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION A-ACCELERATORS SPECTROMETERS DETECTORS AND ASSOCIATED EQUIPMENT, 2011, 651 (01) : 253 - 257
[28] Progress in in-situ CO2-sorption for enhanced hydrogen production
Sikarwar, Vineet Singh
Pfeifer, Christoph
Ronsse, Frederik
Pohorely, Michael
Meers, Erik
Kaviti, Ajay Kumar
Jeremias, Michal
PROGRESS IN ENERGY AND COMBUSTION SCIENCE, 2022, 91
[29] In-situ observation of hydrogen hot trapping from molten lithium with yttrium
Yagi, Juro
Suzuki, Akihiro
Terai, Takayuki
Muroga, Takeo
Tanaka, Satoru
FUSION ENGINEERING AND DESIGN, 2009, 84 (7-11) : 1993 - 1996
[30] Effect of in-situ and ex-situ injection of steam on staged-gasification for hydrogen production
Huo, Xiaodong
Xiao, Jun
Ye, Jiandong
INTERNATIONAL JOURNAL OF HYDROGEN ENERGY, 2020, 45 (16) : 9428 - 9439

← 1 2 3 4 5 →