Simultaneously improving thermal conductivity, mechanical properties and metal fluidity through Cu alloying in Mg-Zn-based alloys

IF 15.8 1区材料科学 Q1 METALLURGY & METALLURGICAL ENGINEERING

Journal of Magnesium and Alloys Pub Date : 2024-09-01 DOI:10.1016/j.jma.2024.04.014

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引用次数: 0

Abstract

Mg-Zn-based alloys have been widely used in computer, communication, and consumer (3C) products due to excellent thermal conductivity. However, it is still a challenge to balance their mechanical performance and thermal conductivity. Here, we investigate microstructure, mechanical performance, thermal conductivity and metal fluidity of Mg-5Zn (wt.%) alloy after Cu alloying by experimental and simulation methods. First, Mg-5Zn alloy consist of α-Mg matrix and interdendritic MgZn phases. As the Cu content increases, however, MgZn phases disappear but intragranular Mg₂Cu and interdendritic MgZnCu phases appear in Mg-5Zn-Cu alloys. Besides, the grain size of α-Mg phase is refined and the volume fraction of MgZnCu phase increases as the Cu content increases. Second, Cu addition is found to improve thermal conductivity of Mg-5Zn alloy remarkably. Especially, Mg-5Zn-4Cu alloy exhibits the best thermal conductivity of 124 W/(m·K), which is mainly due to the significant reduction in both solid solubility of Zn in the α-Mg matrix and lattice distortion of α-Mg matrix. Moreover, a stable crystal structure of MgZnCu phase also contributes to an increased thermal conductivity based on first principles and molecular dynamics simulations. Third, Cu addition simultaneously enhances strength and ductility of Mg-5Zn alloy. Tensile yield strength and elongation of Mg-5Zn-6Cu alloy reach 117 MPa and 18.0 %, respectively, which is a combined result of refinement, solution, second phase, and dislocation strengthening. Finally, combined with a phase field simulation, we found that Cu addition enhances metal fluidity of Mg-5Zn alloy. On the one hand, Cu alloying not only delays dendrite growth but also prolongs solidification time. On the other hand, MgZnCu phase stabilizes the dendrite growth of the α-Mg phases by reducing energy consumption during solidification of liquid metal. This work demonstrates that Cu alloying is an ideal strategy for synergistically improving the thermal conductivity, mechanical performance and metal fluidity of Mg-based alloys.

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通过在镁锌基合金中加入铜合金，同时提高导热性、机械性能和金属流动性

镁锌基合金具有出色的导热性，已被广泛应用于计算机、通信和消费类（3C）产品中。然而，如何平衡其机械性能和导热性能仍然是一个挑战。在此，我们通过实验和模拟方法研究了铜合金化后 Mg-5Zn (wt.%) 合金的微观结构、机械性能、导热性和金属流动性。首先，Mg-5Zn 合金由 α-Mg 基体和树枝状 MgZn 相组成。然而，随着铜含量的增加，Mg-5Zn-Cu 合金中的 MgZn 相消失了，但出现了粒内 Mg2Cu 相和树枝间 MgZnCu 相。此外，随着铜含量的增加，α-镁相的晶粒细化，MgZnCu 相的体积分数增加。其次，铜的加入明显改善了 Mg-5Zn 合金的导热性。尤其是 Mg-5Zn-4Cu 合金的热导率达到了 124 W/(m-K)，这是由于 Zn 在 α-Mg 基体中的固溶性和 α-Mg 基体的晶格畸变都显著降低。此外，根据第一原理和分子动力学模拟，稳定的 MgZnCu 相晶体结构也有助于提高热导率。第三，铜的加入同时增强了 Mg-5Zn 合金的强度和延展性。Mg-5Zn-6Cu 合金的拉伸屈服强度和伸长率分别达到 117 兆帕和 18.0%，这是细化、固溶、第二相和位错强化的综合结果。最后，结合相场模拟，我们发现 Cu 的加入增强了 Mg-5Zn 合金的金属流动性。一方面，铜合金不仅能延迟枝晶的生长，还能延长凝固时间。另一方面，MgZnCu 相通过减少液态金属凝固过程中的能量消耗，稳定了 α-Mg 相的枝晶生长。这项研究表明，铜合金是协同改善镁基合金导热性、机械性能和金属流动性的理想策略。

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来源期刊

Journal of Magnesium and Alloys Engineering-Mechanics of Materials

CiteScore

20.20

自引率

14.80%

发文量

审稿时长

59 days

期刊介绍： The Journal of Magnesium and Alloys serves as a global platform for both theoretical and experimental studies in magnesium science and engineering. It welcomes submissions investigating various scientific and engineering factors impacting the metallurgy, processing, microstructure, properties, and applications of magnesium and alloys. The journal covers all aspects of magnesium and alloy research, including raw materials, alloy casting, extrusion and deformation, corrosion and surface treatment, joining and machining, simulation and modeling, microstructure evolution and mechanical properties, new alloy development, magnesium-based composites, bio-materials and energy materials, applications, and recycling.