| 1 |
Microstructural details of hydrogen diffusion and storage in Ti-V-Cr alloys activated through surface and bulk severe plastic deformation
Novelli M, Edalati K, Itano S, Li HW, Akiba E, Horita Z, Grosdidier T
International Journal of Hydrogen Energy, 45(8), 5326, 2020 |
| 2 |
Superhydrophobic NiTi shape memory alloy surfaces fabricated by anodization and surface mechanical attrition treatment
Ou SF, Wang KK, Hsu YC
Applied Surface Science, 425, 594, 2017 |
| 3 |
Enhanced Enhanced bonding property of cold-sprayed Zn-Al coating on interstitial-free steel substrate with a nanostructured surface layer
Liang YL, Wang ZB, Zhang J, Zhang JB, Lu K
Applied Surface Science, 385, 341, 2016 |
| 4 |
Microstructure and thermal stability of bulk nanocrystalline alloys produced by surface mechanical attrition treatment
Liu WB, Zhang C, Yang ZG, Xia ZX
Applied Surface Science, 292, 556, 2014 |
| 5 |
A new way to synthesize carbon nanofiber film on bulk titanium via hybrid surface mechanical attrition treatment
Yang XF, Lu J
Applied Surface Science, 264, 191, 2013 |
| 6 |
Effect of surface mechanical attrition treatment (SMAT) on microhardness, surface roughness and wettability of AISI 316L
Arifvianto B, Suyitno, Mahardika M, Dewo P, Iswanto PT, Salim UA
Materials Chemistry and Physics, 125(3), 418, 2011 |
| 7 |
Iron-rich layer introduced by SMAT and its effect on corrosion resistance and wear behavior of 2024 Al alloy
Wen L, Wang YM, Zhou Y, Guo LX, Ouyang JH
Materials Chemistry and Physics, 126(1-2), 301, 2011 |
| 8 |
The effect of nanostructured surface layer on the fatigue behaviors of a carbon steel
Li D, Chen HN, Xu H
Applied Surface Science, 255(6), 3811, 2009 |
| 9 |
Nanocrystalline formation during mechanical attrition of cobalt
Zhou J, Sun C, Wu X, Tao N, Liu G, Meng X, Hong Y
Materials Science Forum, 503-504, 751, 2006 |
| 10 |
Effect of SurfaceNanoCrystallization on tribological properties of Stainless Steel
Roland T, Retraint D, Lu K, Lu J
Materials Science Forum, 524-525, 717, 2006 |
