不同元素涂层对真空烧结金刚石/铜复合材料界面特性和热导率的影响

Q. W. Zhou, L. Bolzoni, F. Yang
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引用次数: 0

摘要

界面结构对提高金刚石/铜复合材料的热导率(TC)具有重要意义,使其成为热管理应用的理想候选材料。在烧结过程中,复合材料界面上形成了 TiC、Cr3C2 和 W2C 碳化物界面层。研究结果表明,这三种复合材料的界面结合强度遵循以下等级结构:Ti-D/Cu超过Cr-D/Cu,Cr-D/Cu又超过W-D/Cu。这种层次结构源于在 950 °C 时达到的不同程度的碳化物涂层完整性。此外,菱形-{100}和-{111}晶面上的涂层形态也各不相同。值得注意的是,在界面碳化物中,TiC 涂层在烧结后表现出最紧凑和连续的结构。因此,Ti-D/Cu 复合材料的密度最高,达到 95.49%,TC 值也高达 317.66 W/mK。对这些复合材料断裂形态的比较分析表明,Ti-D/Cu 具有最牢固的界面结合,表现出晶粒内断裂机制。这项研究为金刚石/铜复合材料的界面设计提供了深刻的见解和理论意义,为其在散热材料中的有效利用铺平了道路。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Effects of different element coatings on the interface characteristics and thermal conductivity of vacuum-sintered diamond/Cu composites
The interface structure holds paramount significance in enhancing the thermal conductivity (TC) of diamond/Cu composites, positioning them as a promising candidate for thermal management applications. Diamond/Cu composites (55% volume fraction) with three distinct interfacial carbides were fabricated via sintering at 950 °C using Cu and diamond powder coated with Ti, Cr, and W. During the sintering process, interfacial layers of TiC, Cr3C2, and W2C carbides formed at the composite interfaces. The findings reveal that the interfacial bonding strength among these three composites adheres to the following hierarchy: Ti-D/Cu exceeds Cr-D/Cu, which surpasses W-D/Cu. This hierarchy stems from the varying degrees of carbide coating integrity attained at 950 °C. Furthermore, the coating morphology differs on the diamond-{100} and -{111} crystal planes. Notably, among the interfacial carbides, TiC coating exhibits the most compact and contiguous structure postsintering. Consequently, Ti-D/Cu composites boast the highest density, reaching 95.49%, along with a remarkable TC of 317.66 W/mK. A comparative analysis of the fracture morphology of these composites reveals that Ti-D/Cu, characterized by the most robust interfacial bonding, exhibits a intransgranular fracture mechanism. This study offers profound insights and theoretical implications for the interface design of diamond/Cu composites, paving the way for their effective utilization in heat dissipation materials.
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