Microstructure and damping properties of LPSO phase dominant Mg-Ni-Y and Mg-Zn-Ni-Y alloys

“…Mg presents a black contrast marked with "A", which is attributed to the low average atomic number. This morphology was also reported in other works on Mg-RE-Ni-based alloys [24,[45][46][47][48] The same characteristics can be illustrated by EDS mapping (corresponding to the region in Figure 3c), as shown in Figure 4. Y element is mainly dissolved in YMgNi 4 and Mg 15 Ni (see Figure 4d).…”

“…Mg presents a black contrast marked with "A", which is attributed to the low average atomic number. This morphology was also reported in other works on Mg-RE-Ni-based alloys [24,[45][46][47][48] It should be noted that large strip shape Mg15NiY can also be observed in the as-cast Mg80Ni14Al2Y4 alloy, indicating Mg15NiY solidified by both proeutectic and eutectic processes. In addition, Al3Ni2Y could not be observed in the EPMA test, possibly due to its low content.…”

Study on Microstructure and Hydrogen Storage Properties of Mg80Ni16−xAlxY4 (x = 2, 4, 8) Alloys

“…Mg presents a black contrast marked with "A", which is attributed to the low average atomic number. This morphology was also reported in other works on Mg-RE-Ni-based alloys [24,[45][46][47][48] The same characteristics can be illustrated by EDS mapping (corresponding to the region in Figure 3c), as shown in Figure 4. Y element is mainly dissolved in YMgNi 4 and Mg 15 Ni (see Figure 4d).…”

“…Mg presents a black contrast marked with "A", which is attributed to the low average atomic number. This morphology was also reported in other works on Mg-RE-Ni-based alloys [24,[45][46][47][48] It should be noted that large strip shape Mg15NiY can also be observed in the as-cast Mg80Ni14Al2Y4 alloy, indicating Mg15NiY solidified by both proeutectic and eutectic processes. In addition, Al3Ni2Y could not be observed in the EPMA test, possibly due to its low content.…”

Study on Microstructure and Hydrogen Storage Properties of Mg80Ni16−xAlxY4 (x = 2, 4, 8) Alloys

“…Heat treatment can readjust the density of dislocations or other defects in the material, eliminate disordered areas, and improve the damping performance of the alloy [ 76 , 77 ]. Ruopeng Lu et al [ 78 ] studied the microstructure, mechanical properties, and damping properties of Mg 95.34 Ni 2 Y 2.66 alloys and Mg 95.34 Zn 1 Ni 1 Y 2.66 alloys, especially the difference in the long-period stacked ordered phase (LPSO) in these two alloys during heat treatment. After two hours of heat treatment at 773 K, the eutectic phase was integrated into the matrix, and the LPSO phase still maintained a constant structure.…”

“…Heat treatment can readjust the density of dislocations or other defects in the material, eliminate disordered areas, and improve the damping performance of the alloy [76,77]. Ruopeng Lu et al [78] alloys with a rod-shaped LSPO phase showed a good damping capacity and exceeded the high damping standard (Q −1 > 0.01). This might be caused by the difference between the second phase and solid solution atom content.…”

Research Progress and the Prospect of Damping Magnesium Alloys

Optimization on microstructure, mechanical properties and damping capacities of duplex structured Mg-8Li-4Zn-1Mn alloys