研究目的
To optimize the laser scanning speed during laser surface processing of a Zr-based bulk metallic glass (BMG) to obtain amorphous structure in the melt zone and nanocomposite structure in the heat affected zone (HAZ), and to study the microstructural characteristics and mechanical properties of the processed zones.
研究成果
The study demonstrated that optimizing laser scanning speed can control the amorphous structure of the laser treated zone and the nanocomposite structure in the HAZ of Zr-based BMGs. A laser speed of 22.6 mm/s was found to be optimal for maintaining the amorphous structure in the melt zone and forming a BMG-B2 nanocomposite structure in the HAZ, which improved mechanical properties. MD simulation revealed that the presence of B2 phase prevents stress reduction during plastic deformation.
研究不足
The study is limited to Zr65.7Ti3.3Al3.7Ni11.7Cu15.6 (wt.%) BMG foils with a 100 μm thickness and specific laser processing conditions. The findings may not be directly applicable to other BMG compositions or processing methods.
1:Experimental Design and Method Selection
Laser surface processing was applied using a WEDGE HF 1064 diode-pumped solid-state Nd:YAG laser with different scan speeds over a square area of 10 mm2.
2:Sample Selection and Data Sources
Zr65.7-Cu15.6-Ni11.7-Al3.7-Ti3.3 (wt.%) BMG foils with a thickness of 100 μm were used as the feedstock.
3:List of Experimental Equipment and Materials
WEDGE HF 1064 diode-pumped solid-state Nd:YAG laser, SS-12 2D-scanning galvanometer, 404-4PD single-axis nanoposition stage, Keyence VHX2000E 3D digital microscope, Jordan Valley Bede D1 high resolution XRD system, Stanton Redcroft STA 1640 differential thermal analyzer, TEM (JEM-2100, Jeol), Bruker HYSITRON TI Premier nano-mechanical test instrument.
4:Experimental Procedures and Operational Workflow
The foils were laser surface treated at different speeds. Microstructure was studied using OM, XRD, DSC, and HRTEM. Nanoindentation testing was employed to evaluate mechanical properties. MD simulation was used to discover deformation mechanisms.
5:Data Analysis Methods
XRD, DSC, HRTEM, and nanoindentation data were analyzed to study microstructural characteristics and mechanical properties. MD simulation results were analyzed to understand deformation mechanisms.
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