Microstructures and Mechanical Properties of Nanocrystalline AZ31 Magnesium Alloy Powders with Submicron TiB2 Additions Prepared by Mechanical Milling

Haiping Zhou,Chengcai Zhang,Hongbin Zhang,Shengxue Qin,Jie Liu,Kuidong Gao,Baokun Han,Jianfeng Qiu,Shuai Sun

doi:10.3390/cryst10060550

Haiping Zhou, Chengcai Zhang + Show 7 more

Open Access

https://doi.org/10.3390/cryst10060550

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Abstract

In this work, nanocrystalline AZ31 magnesium alloy powders, reinforced by submicron TiB2 particles, were prepared via mechanical milling. It was found that TiB2 particles stimulated the fracture and welding of AZ31/TiB2 powders, leading to the acceleration of the milling process. Meanwhile, the TiB2 particles were refined to submicron-scale size during the milling process, and their distribution was uniform in the Mg matrix. In addition, the matrix was significantly refined during the milling process, which was also accelerated by the TiB2 particles. The formation of grain boundary segregation layers also led to the weakened TiB2 peaks in the XRD patterns during the mechanical milling. The grain sizes of AZ31–2.5 wt % TiB2, AZ31–5 wt % TiB2 and AZ31–10 wt % TiB2 powders were refined to 53 nm, 37 nm and 23 nm, respectively, after milling for 110 h. Under the combined effect of the nanocrystalline matrix and the well-dispersed submicron TiB2 particles, the AZ31/TiB2 composites exhibited excellent micro-hardness. For the AZ31–10 wt % TiB2 composite, the micro-hardness was enhanced to 153 HV0.5.

Highlights

At present, the development of high-strength light alloys has been required to meet the light-weight requirements, which is of great significance for energy saving in structural applications [1]
In order to extend the structural application of Mg alloys, it is necessary to search for effective methods to further strengthen the commercial Mg alloys
It is widely proposed that grain refinement is an important method of strengthening metallic materials, while the nanocrystalline (NC) and ultrafine-grained (UFG) materials can exhibit better mechanical properties when compared with conventional coarse-grained materials [7,8]

Summary

Introduction

The development of high-strength light alloys has been required to meet the light-weight requirements, which is of great significance for energy saving in structural applications [1]. Aydin et al [17] prepared Mg/B4 C composites via powder metallurgy, while the increments on compressive yield strength and hardness reached about 69.5% and 63.9%, for 30 wt % B4 C, as compared to pure Mg. Rahmany-Gorji et al [20] studied the influence of Al2 O3 micro-particles on the properties of ZX51 alloy; the hardness of ZX51/Al2 O3 composites increased to 72.0 HB, while the hardness was only 58.1 HB for ZX51 alloy. Aydin et al [23] studied the properties of hot-pressed TiB2 particulate-reinforced Mg matrix composites, and their hardness increment was 65.3% with 30 wt % TiB2 particles, as compared to pure Mg. At present, investigations into Mg/TiB2 composites are still rather limited, and more works should be carried out to realize the great potential of TiB2 additions in Mg matrix composites. The properties and strengthening mechanism of the composites were analyzed in detail

Experimental Procedures

Evolution of TiB2 Particles

XRD Analysis

TEM Analysis

Hardness

Conclusions