Scale-dependent behavior of microstructure characteristics of laser powder bed fused TiB2 /AlSi10Mg composite

doi:10.1016/j.jmst.2024.06.004

Abstract

Abstract: The pre-alloyed TiB2 /AlSi10Mg composite, a new high-strength aluminum alloy developed for laser pow-der bed fusion (LPBF) technology, offers promising applications in lightweight and multi-scaled structures. However, thermal behavior during LPBF is markedly scale-dependent, leading to microstructural varia-tions that significantly affect the load-bearing capacity of multi-scaled structures. Therefore, this study systematically investigates the scale-dependent behavior of microstructure characteristics of this com-posite. Utilizing a hatching scanning strategy, it was found that the marginal zones of samples are pre-dominantly composed of coarse Al cell and Al grain structures, contrasting with the fine microstructures in the central zones. With increasing structure scale, cell and grain structures in both the marginal and central zones become more refined, with cell sizes reducing by 49 %-72 % (～3.02 μm→ 0.86-1.55 μm). Particularly, the minimum-scaled structures also feature broken eutectic Si particles and nanopores. The essence is primarily due to the low heat dissipation with higher peak temperature and longer duration time at high temperatures in both the small-scale structures and marginal zones. Additionally, smaller structures correlate with reduced microhardness and tensile strength, accompanied by the “softening”of the marginal zones. The strength of the minimum-scaled structure is only half that of the standard sample. Our findings suggest a scale threshold of 2.0 mm for researching scale effect. Encouragingly, in-corporating additional contour scanning significantly counteracts the adverse influence of the scale effect. Owing to the combined influence of extended inter-layer time and laser remelting, all samples demon-strate a distinctly refined microstructure. This results in consistently high levels of microhardness and strength, with the “hardening”of the marginal zones. Eventually, the relationship between mechanical properties and microstructure sizes is established. This study provides valuable insights into the innova-tive designs and engineering applications of multi-scaled structures in LPBF using various materials.

Key words: Scale-dependent behavior, Microstructure characteristics, Scanning strategy, Laser powder bed fusion

Zhe Feng, Geng Wang, Yongxia Wang, Mingji Dang, Wei Fan, Hua Tan, Zhiwei Hao, Siyu Zhang, Yuguang Chen, Yijie Peng, Tianchi Zhang, Shuoqing Shi, Xufei Lu, Fengying Zhang, Xin Lin, Weidong Huang. Scale-dependent behavior of microstructure characteristics of laser powder bed fused TiB₂ /AlSi10Mg composite[J]. J. Mater. Sci. Technol., 2025, 212: 158-172.

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Scale-dependent behavior of microstructure characteristics of laser powder bed fused TiB₂ /AlSi10Mg composite

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