This study investigates the impact of Zn alloying on the dispersion of the reinforcing particle in Mg_(2)Sn/Mg composites.In the composite,Zn manifests in three distinct forms:Zn segregation layer between Mg–Mg_(2)Sn...This study investigates the impact of Zn alloying on the dispersion of the reinforcing particle in Mg_(2)Sn/Mg composites.In the composite,Zn manifests in three distinct forms:Zn segregation layer between Mg–Mg_(2)Sn,the solid solution and the MgZn_(2)phase.First-principles calculations confirm that the formation of Zn segregation layer decreases the interfacial energy of the Mg–Mg_(2)Sn.Importantly,this segregation layer significantly enhances the comigration capability of Mg_(2)Sn particles with Mg matrix during sintering flow,effectively hindering the agglomeration and coarsening of the nano-sized reinforcing phase.The dense and uniformly distributed nano-sized Mg_(2)Sn significantly increases the activity of non-basal slip,ensuring good elongation of the composite while enhancing strength.It can be concluded that enhancing the comigration-ability of reinforcing particles with the matrix is an effective strategy for achieving controlled dispersion of high-volume reinforcing particles and an excellent combination of strength and ductility in magnesium matrix composites.展开更多
The microwave absorbents of Fe and C nanoparticles as magnetic loss and dielectric loss material respectively were composited with the polyvinyl alcohol(PVA)as binder by spray granulation method,The electromagnetic pa...The microwave absorbents of Fe and C nanoparticles as magnetic loss and dielectric loss material respectively were composited with the polyvinyl alcohol(PVA)as binder by spray granulation method,The electromagnetic parameters of Fe and C composite particles were analyzed by vector network.The complex permittivity and magnetic permeability of Fe and C composite particles matched well with increasing C nanoparticle content,and then the microwave loss property was improved.A minimum reflection loss(RL)of-42.7 dB at 3.68 GHz for a composite with 4.6 mm in thickness can be obtained when the content ratio of the C nanoparticles,the modified Fe nanoparticles and the PVA is 21:49:30(Sample 3).展开更多
More requirements of electromagnetic interference(EMI) shielding performance are put forward for lightweight structural materials due to the development of aerospace and 5G communications. Herein, graphene oxide(GO) d...More requirements of electromagnetic interference(EMI) shielding performance are put forward for lightweight structural materials due to the development of aerospace and 5G communications. Herein, graphene oxide(GO) decorated with SnO_(2) coating is introduced as reinforcement into AZ31 Mg alloy. During the smelting process, the MgO layer is in situ gernerated at interface between GO and the molten Mg alloy matrix by consuming SnO_(2). In the solid state, such kind of interface structure can improve the GO-Mg interface bonding intensity,also significantly generate stacking faults. The AZ31 composite reinfoced by trace modified GO(0.1 wt%) exhibits high ultimate strength and almost the same elongation with AZ31 alloy. Compared with AZ31 alloy, the yield strength and ultimate tensile strength of composite are increased by 33.5% and 23.7%, respectively. Meanwhile, the multi-level electromagnetic reflection from the multi-layer structure of GO and the interface polarization caused by the MgO mid-layer can significantly improve EMI shielding performance. The appropriate interface design strategy achieves the effect of “two birds with one stone”.展开更多
基金support provided by the National Natural Science Foundation of China(No.52174357)Fundamental Research Funds for the Central Universities(No.DUT21LAB132)The Basic and Applied Basic Research Major Programme of Guangdong Province,China(No.2021B0301030003)。
文摘This study investigates the impact of Zn alloying on the dispersion of the reinforcing particle in Mg_(2)Sn/Mg composites.In the composite,Zn manifests in three distinct forms:Zn segregation layer between Mg–Mg_(2)Sn,the solid solution and the MgZn_(2)phase.First-principles calculations confirm that the formation of Zn segregation layer decreases the interfacial energy of the Mg–Mg_(2)Sn.Importantly,this segregation layer significantly enhances the comigration capability of Mg_(2)Sn particles with Mg matrix during sintering flow,effectively hindering the agglomeration and coarsening of the nano-sized reinforcing phase.The dense and uniformly distributed nano-sized Mg_(2)Sn significantly increases the activity of non-basal slip,ensuring good elongation of the composite while enhancing strength.It can be concluded that enhancing the comigration-ability of reinforcing particles with the matrix is an effective strategy for achieving controlled dispersion of high-volume reinforcing particles and an excellent combination of strength and ductility in magnesium matrix composites.
基金the support from the National Natural Science Foundation of China(No.51171033)the Fundamental Research Funds for the Central Universities(DUT15LAB05,DUT16LAB03)
文摘The microwave absorbents of Fe and C nanoparticles as magnetic loss and dielectric loss material respectively were composited with the polyvinyl alcohol(PVA)as binder by spray granulation method,The electromagnetic parameters of Fe and C composite particles were analyzed by vector network.The complex permittivity and magnetic permeability of Fe and C composite particles matched well with increasing C nanoparticle content,and then the microwave loss property was improved.A minimum reflection loss(RL)of-42.7 dB at 3.68 GHz for a composite with 4.6 mm in thickness can be obtained when the content ratio of the C nanoparticles,the modified Fe nanoparticles and the PVA is 21:49:30(Sample 3).
基金financial support provided by the National Natural Science Foundation of China (No.52174357)Fundamental Research Funds for the Central Universities (No.DUT21LAB132)。
文摘More requirements of electromagnetic interference(EMI) shielding performance are put forward for lightweight structural materials due to the development of aerospace and 5G communications. Herein, graphene oxide(GO) decorated with SnO_(2) coating is introduced as reinforcement into AZ31 Mg alloy. During the smelting process, the MgO layer is in situ gernerated at interface between GO and the molten Mg alloy matrix by consuming SnO_(2). In the solid state, such kind of interface structure can improve the GO-Mg interface bonding intensity,also significantly generate stacking faults. The AZ31 composite reinfoced by trace modified GO(0.1 wt%) exhibits high ultimate strength and almost the same elongation with AZ31 alloy. Compared with AZ31 alloy, the yield strength and ultimate tensile strength of composite are increased by 33.5% and 23.7%, respectively. Meanwhile, the multi-level electromagnetic reflection from the multi-layer structure of GO and the interface polarization caused by the MgO mid-layer can significantly improve EMI shielding performance. The appropriate interface design strategy achieves the effect of “two birds with one stone”.
