Effect of AlN coating on hydrogen permeability and surface structure of VT6 alloy by vacuum arc ion plating

doi:10.1088/1674-1056/ab3a8e

Abstract We study the absorption of hydrogen of metal by the permeability method. With the help of the gas reaction controller (GRC), the absorptive capacity of hydrogen, which is a function of time, temperature and pressure, can be recorded. The effect of the performance of the hydrogen permeability of AlN coating on the titanium alloy surface structure is studied. In the research, the AlN is selected to be added to the titanium alloy sample VT6, and the properties of the titanium alloy are investigated, and the hydrogen absorption rate of the coating is calculated by performing the hydrogen saturation of the test sample. The results show that under 600 ℃ the AlN film reduces the hydrogen absorption rate of titanium alloy and improves the surface properties of VT6 alloy.

Keywords: titanium alloy ion plating aluminum nitride hydrogen

Received: 12 May 2019
Revised: 05 August 2019
Accepted manuscript online:

PACS:	81.05.Bx	(Metals, semimetals, and alloys)
	81.15.Jj	(Ion and electron beam-assisted deposition; ion plating)
	81.05.Je	(Ceramics and refractories (including borides, carbides, hydrides, nitrides, oxides, and silicides))

Fund: Project supported by the China Scholarship Council.

Corresponding Authors: Zi-Yi Ding
E-mail: lapd@live.cn

Cite this article:

Zi-Yi Ding(丁子祎) Effect of AlN coating on hydrogen permeability and surface structure of VT6 alloy by vacuum arc ion plating 2019 Chin. Phys. B 28 108101

[1]	Elanchezhian C, Ramnath B V, Ramakrishnan G, et al. 2018 Mater. Today: Proc. 5 1211
[2]	Bewlay B P, Nag S, Suzuki A, et al. 2016 Mater. High Temp. 33 549
[3]	Xu, J J, Cheung H Y and Shi S Q 2007 J. Alloys Compd. 436 82
[4]	Tal-Gutelmacher E and Eliezer D 2005 J. Alloys Compd. 404 621
[5]	Kudiiarov V N, Gulidova L V, Pushilina N S, et al. 2013 Adv. Mater. Res. 740 690

[1]	Strain engineering and hydrogen effect for two-dimensional ferroelectricity in monolayer group-IV monochalcogenides MX (M =Sn, Ge; X=Se, Te, S) Maurice Franck Kenmogne Ndjoko, Bi-Dan Guo(郭必诞), Yin-Hui Peng(彭银辉), and Yu-Jun Zhao(赵宇军). Chin. Phys. B, 2023, 32(3): 036802.
[2]	Effects of π-conjugation-substitution on ESIPT process for oxazoline-substituted hydroxyfluorenes Di Wang(汪迪), Qiao Zhou(周悄), Qiang Wei(魏强), and Peng Song(宋朋). Chin. Phys. B, 2023, 32(2): 028201.
[3]	Concerted versus stepwise mechanisms of cyclic proton transfer: Experiments, simulations, and current challenges Yi-Han Cheng(程奕涵), Yu-Cheng Zhu(朱禹丞), Xin-Zheng Li(李新征), and Wei Fang(方为). Chin. Phys. B, 2023, 32(1): 018201.
[4]	Synthesis of hexagonal boron nitride films by dual temperature zone low-pressure chemical vapor deposition Zhi-Fu Zhu(朱志甫), Shao-Tang Wang(王少堂), Ji-Jun Zou(邹继军), He Huang(黄河), Zhi-Jia Sun(孙志嘉), Qing-Lei Xiu(修青磊), Zhong-Ming Zhang(张忠铭), Xiu-Ping Yue(岳秀萍), Yang Zhang(张洋), Jin-Hui Qu(瞿金辉), and Yong Gan(甘勇). Chin. Phys. B, 2022, 31(8): 086103.
[5]	Laser fragmentation in liquid synthesis of novel palladium-sulfur compound nanoparticles as efficient electrocatalysts for hydrogen evolution reaction Guo-Shuai Fu(付国帅), Hong-Zhi Gao(高宏志), Guo-Wei Yang(杨国伟), Peng Yu(于鹏), and Pu Liu(刘璞). Chin. Phys. B, 2022, 31(7): 077901.
[6]	Assessing the effect of hydrogen on the electronic properties of 4H-SiC Yuanchao Huang(黄渊超), Rong Wang(王蓉), Yiqiang Zhang(张懿强), Deren Yang(杨德仁), and Xiaodong Pi(皮孝东). Chin. Phys. B, 2022, 31(5): 056108.
[7]	Transition metal anchored on C₉N₄ as a single-atom catalyst for CO₂ hydrogenation: A first-principles study Jia-Liang Chen(陈嘉亮), Hui-Jia Hu(胡慧佳), and Shi-Hao Wei(韦世豪). Chin. Phys. B, 2022, 31(10): 107306.
[8]	C₉N₄ as excellent dual electrocatalyst: A first principles study Wei Xu(许伟), WenWu Xu(许文武), and Xiangmei Duan(段香梅). Chin. Phys. B, 2021, 30(9): 096802.
[9]	Numerical investigation of radio-frequency negative hydrogen ion sources by a three-dimensional fluid model Ying-Jie Wang(王英杰), Jia-Wei Huang(黄佳伟), Quan-Zhi Zhang(张权治), Yu-Ru Zhang(张钰如), Fei Gao(高飞), and You-Nian Wang(王友年). Chin. Phys. B, 2021, 30(9): 095205.
[10]	A simple method to synthesize worm-like AlN nanowires and its field emission studies Qi Liang(梁琦), Meng-Qi Yang(杨孟骐), Chang-Hao Wang(王长昊), and Ru-Zhi Wang(王如志). Chin. Phys. B, 2021, 30(8): 087302.
[11]	Role of graphene in improving catalytic behaviors of AuNPs/MoS₂/Gr/Ni-F structure in hydrogen evolution reaction Xian-Wu Xiu(修显武), Wen-Cheng Zhang(张文程), Shu-Ting Hou(侯淑婷), Zhen Li(李振), Feng-Cai Lei(雷风采), Shi-Cai Xu(许士才), Chong-Hui Li(李崇辉), Bao-Yuan Man(满宝元), Jing Yu(郁菁), and Chao Zhang(张超). Chin. Phys. B, 2021, 30(8): 088801.
[12]	Helium-hydrogen synergistic effects on swelling in in-situ multiple-ion beams irradiated steels Haocheng Liu(刘昊成), Jia Huang(黄嘉), Liuxuan Cao(曹留煊), Yue Su(苏悦), Zhiying Gao(高智颖), Pengfei Ma(马鹏飞), Songqin Xia(夏松钦), Wei Ge(葛伟), Qingyuan Liu(刘清元), Shuang Zhao(赵双), Yugang Wang(王宇钢), Jinchi Huang(黄金池), Zhehui Zhou(周哲辉), Pengfei Zheng(郑鹏飞), and Chenxu Wang(王晨旭). Chin. Phys. B, 2021, 30(8): 086106.
[13]	Modeling hydrogen exchange of proteins by a multiscale method Wentao Zhu(祝文涛), Wenfei Li(李文飞), and Wei Wang(王炜). Chin. Phys. B, 2021, 30(7): 078701.
[14]	Design and simulation of AlN-based vertical Schottky barrier diodes Chun-Xu Su(苏春旭), Wei Wen(温暐), Wu-Xiong Fei(费武雄), Wei Mao(毛维), Jia-Jie Chen(陈佳杰), Wei-Hang Zhang(张苇杭), Sheng-Lei Zhao(赵胜雷), Jin-Cheng Zhang(张进成), and Yue Hao(郝跃). Chin. Phys. B, 2021, 30(6): 067305.
[15]	Hydrogen-induced dynamic slowdown of metallic glass-forming liquids Jin-Ai Gao(高津爱), Hai-Shen Huang(黄海深), and Yong-Jun Lü(吕勇军). Chin. Phys. B, 2021, 30(6): 066301.

No Suggested Reading articles found!

Viewed

Full text

Abstract

Cited

Metrics
Related Articles

Effect of AlN coating on hydrogen permeability and surface structure of VT6 alloy by vacuum arc ion plating

Cite this article:

Online attention