Influence of Surface Nanocrystallization on Ti Ion Implantation of Pure Iron

doi:10.1016/j.jmst.2015.01.001

Abstract

Abstract: In order to increase the depth or concentration of Ti ion implantation of pure iron, the surface mechanical attrition treatment (SMAT), which can fabricate a nanometer-grained surface layer without porosity and contamination in a pure iron plate, was used before ion implantation. Ti ion was implanted into the SMA treated sample and coarse-grained counterpart by using a metal vapor vacuum arc source implanter. The changing of depth and concentration of Ti was studied in a function of implantation time. By optical microscopy, transmission electron microscopy and X-ray diffraction, the grain size of the nano structured surface was studied. Micro-hardness, friction and wear behavior of nano surface layers were studied. By energy dispersive X-ray spectroscopy and Auger electron spectroscopy, the chemical composition and concentration of Ti ion in the surface implantation layer were studied. Experimental results showed that the concentration of Ti increased dramatically compared with untreated coarse-grained samples, which is attributed to the existence of higher density of defects (supersaturated vacancies, dislocations, non-equilibrium grain boundaries etc.) and compression stress field in the SMA treated nanocrystallined surface layer. The interaction between the defects and the implanted solute atoms leads to the increment of solid solubility. But the implantation depth showed inconspicuous change. It is shown that the ion range is just relevant to the energy and mass of the ion, dose of injection, the mass and density of target material.

Key words: Pure iron, Surface mechanical attrition treatment, Ion implantation

Xu Li, Yanli An, Yinghui Wei, Huayun Du, Lifeng Hou, Chunli Guo, Hongbo Qu, Yide Wang. Influence of Surface Nanocrystallization on Ti Ion Implantation of Pure Iron[J]. J. Mater. Sci. Technol., 2015, 31(3): 305-310.

Figures/Tables 8

Microscopic cross-sectional observation of pure iron after SMAT for (a) 15 min, (b) 30 min, (c) 60 min and (d) 90 min, respectively.

(a) Bright-field

(b) dark-field TEM images showing the equiaxed nano-sized grains and (c) the corresponding selected area electron diffraction (SAED) pattern of the top surface layer of the SMAT sample for 60 min.

X-ray patterns of the Fe samples after SMAT with different depth.

Variations of the grain/cell size, the mean microstrain and the micro-hardness with the depth from the treated surface of the Fe sample. (The grain/cell size was determined by XRD and TEM, and the mean microstrain was determined by XRD).

Variations of the micro-hardness with the depth from the treated surface of the iron sample.

Variations of the friction coefficient (a) and the wear weight loss (b) as function of loads for SMAT and coarse-grained iron specimens.

Titanium concentration profiles of the SMAT sample and coarse-grained sample along the depth by AES for pure iron.

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