NANO-POROUS COATINGS FOR GAS RETENTION STUDIES

被引:0
作者
Ruset, C. [1 ]
Grigore, E. [1 ]
Rasinski, M. [2 ]
Fortuna, E. [2 ]
Grzonka, J. [2 ,5 ]
Gherendi, M. [1 ]
Luculescu, C. [1 ]
Barradas, N. P. [3 ]
Alves, E. [3 ]
Hakola, A. [4 ]
机构
[1] Natl Inst Laser Plasma & Radiat Phys, Atomistilor St, Magurele 077125, Romania
[2] Warsaw Univ Technol, Fac Mat Sci & Engn, Woloska 141 St, PL-02507 Warsaw, Poland
[3] Univ Lisbon, Inst Super Tecn, IPFN, Av Rovisco Pais, P-1049001 Lisbon, Portugal
[4] VTT Tech Res Ctr Finland, POB 1000, FI-02044 Espoo, Finland
[5] Inst Elect Mat Technol, Wolczynska 133, PL-01919 Warsaw, Poland
来源
ROMANIAN REPORTS IN PHYSICS | 2019年 / 71卷 / 01期
基金
欧盟地平线“2020”;
关键词
nano-porous coatings; tungsten; argon; ION-IMPLANTATION;
D O I
暂无
中图分类号
O4 [物理学];
学科分类号
0702 ;
摘要
One way to produce coatings with high gas retaining capability is to manipulate their structure towards a nano-porous one. Combined Magnetron Sputtering and Ion Implantation (CMSII) technique was used to produce pores of 1-10 nm in tungsten layers of about 1 mu m in thickness. STEM, EDX, RBS, TDS and GDOES techniques were used for analyses of these layers. By heating the layer at 950 degrees C the pores size increased up to 30 nm. The total amount of Ar retained in these layers was 3.9. 10(20) atoms/m(2) while in compact W coating of the same thickness only 2.7. 10(19) atoms/m(2) it was found.
引用
收藏
页数:10
相关论文
共 50 条
[41]   Tribological studies of Zr-implanted PVD TiN coatings deposited on stainless steel substrates [J].
Purushotham, KP ;
Ward, LP ;
Brack, N ;
Pigram, PJ ;
Evans, P ;
Noorman, H ;
Manory, RR .
WEAR, 2003, 254 (7-8) :589-596
[42]   Deuterium retention in chemically vapor deposited tungsten carbide coatings and hot-rolled tungsten exposed to low-energy deuterium plasma [J].
Alimov, Vladimir Kh ;
Roth, Joachim .
TUNGSTEN, 2022, 4 (01) :10-19
[43]   Deuterium retention in chemically vapor deposited tungsten carbide coatings and hot-rolled tungsten exposed to low-energy deuterium plasma [J].
Vladimir Kh. Alimov ;
Joachim Roth .
Tungsten, 2022, 4 :10-19
[44]   Effects of fabrication conditions on the microstructure, pore characteristics and gas retention of pure tungsten prepared by laser powder bed fusion [J].
Yamamoto, Takafumi ;
Hara, Masanori ;
Hatano, Yuji .
INTERNATIONAL JOURNAL OF REFRACTORY METALS & HARD MATERIALS, 2021, 95 (95)
[45]   IR Spectrometric Studies of CCL4 and Ar Gas Mixtures [J].
Korshikov, E. ;
Sokolov, D. ;
Potapchenko, A. ;
Aldiyarov, A. .
JOURNAL OF LOW TEMPERATURE PHYSICS, 2023, 211 (1-2) :1-10
[46]   IR Spectrometric Studies of CCL4 and Ar Gas Mixtures [J].
E. Korshikov ;
D. Sokolov ;
A. Potapchenko ;
A. Aldiyarov .
Journal of Low Temperature Physics, 2023, 211 :1-10
[47]   Formation conditions of the tungsten porous thin film with pulsed laser deposition under various gas atmosphere [J].
Kodate, S. ;
Shi, Q. ;
Kajita, S. .
JAPANESE JOURNAL OF APPLIED PHYSICS, 2024, 63 (09)
[48]   Comparison testing of diamond-like a-C:H coatings prepared in plasma cathode-based gas discharge and ta-C coatings deposited by vacuum arc [J].
Gavrilov, N. V. ;
Mamaev, A. S. ;
Plotnikov, S. A. ;
Rubshtein, A. P. ;
Trakhtenberg, I. Sh. ;
Ugov, V. A. .
SURFACE & COATINGS TECHNOLOGY, 2010, 204 (24) :4018-4024
[49]   Animal-friedly gas stunning of broilers and meat quality aspect Part 2: Alternative gas stunning - Studies [J].
Machold, Ulrike .
FLEISCHWIRTSCHAFT, 2021, 101 (01) :84-89
[50]   Cold plasma studies on the influence of surface microstructured thickness in the secondary electron emission from tungsten coatings [J].
de Castro, A. ;
Oyarzabal, E. ;
Tabares, F. L. .
NUCLEAR MATERIALS AND ENERGY, 2023, 34
12345