Improved Bending Strength and Thermal Conductivity of Diamond/Al Composites with Ti Coating Fabricated by Liquid–Solid Separation Method

Zhou, Hongyu; Jia, Qijin; Sun, Jing; Li, Yaqiang; He, Yinsheng; Bi, Wensi; Zheng, Wenyue

doi:10.3390/ma17071485

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2024

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Cited by 2 publications

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“…It was observed that higher model accuracy could be achieved in samples with a larger cladding layer thickness. Meanwhile, Zhou et al [ 12 ] employed their independently designed liquid–solid separation method to fabricate diamond/Al composites reinforced with 40 vol.% diamond particles, achieving high thermal conductivity. This innovative approach demonstrates the potential for producing composites with superior thermal properties for advanced industrial applications.…”

Section: Contributionsmentioning

confidence: 99%

Recent Progress in Additive Manufacturing of Alloys and Composites

Gao,

Lu,

Zhao

et al. 2024

Materials

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Section: Contributionsmentioning

confidence: 99%

Recent Progress in Additive Manufacturing of Alloys and Composites

Gao,

Lu,

Zhao

et al. 2024

Materials

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Preparation and Property Modulation of Multi-Grit Diamond/Aluminum Composites Based on Interfacial Strategy

Wu,

Yang,

Chen

et al. 2024

Metals

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The development of electronic devices has a tendency to become more complicated in structure, more integrated in function, and smaller in size. The heat flow density of components continues to escalate, which urgently requires the development of heat sink materials with high thermal conductivity and a low coefficient of expansion. Diamond/aluminum composites have become the research hotspot of thermal management materials with excellent thermophysical and mechanical properties, taking into account the advantages of light weight. In this paper, diamond/Al composites are prepared by combining aluminum as matrix and diamond reinforcement through the discharge plasma sintering (SPS) method. The micro-interfacial bonding state of diamond and aluminum is changed by adjusting the particle size of diamond, and the macroscopic morphology performance of the composites is regulated. Through this, the flexible design of diamond/Al performance can be achieved. As a result, when 150 μm diamond powder and A1-12Si powder were used for the composite, the thermal conductivity of the obtained specimens was up to 660.1 W/mK, and the coefficient of thermal expansion was 5.63 × 10−6/K, which was a good match for the semiconductor material. At the same time, the bending strength is 304.6 MPa, which can satisfy the performance requirements of heat-sinking materials in the field of electronic packaging.

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Improved Bending Strength and Thermal Conductivity of Diamond/Al Composites with Ti Coating Fabricated by Liquid–Solid Separation Method

Cited by 2 publications

References 39 publications

Recent Progress in Additive Manufacturing of Alloys and Composites

Recent Progress in Additive Manufacturing of Alloys and Composites

Preparation and Property Modulation of Multi-Grit Diamond/Aluminum Composites Based on Interfacial Strategy

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