材料科学
微通道
钻石
散热片
表面粗糙度
制作
光电子学
微加工
波纹度
表面光洁度
小型化
电子设备和系统的热管理
热的
激光器
光学
微流控
复合材料
温度测量
皮秒
金刚石材料性能
传热
垂直腔面发射激光器
表面处理
热阻
激光打孔
作者
Yichen Huang,Zihao Zhang,X. A. Wang,Liqun Li,Lijun Yang
摘要
The trend toward integration and miniaturization in modern chips poses a significant challenge to the thermal management of devices. Traditional thermal interface materials can no longer meet the heat dissipation requirements of high-power devices. Utilizing high-thermal-conductivity diamond for microfluidic cooling appears to be a promising solution. In this study, polycrystalline diamond was processed using an infrared picosecond laser system. We investigated the influence of processing parameters on the degree of diamond graphitization, as well as on the dimensions and taper of the fabricated microchannels. By optimizing these parameters to minimize graphitization, low-sidewall-taper (0.9°) diamond microchannels with an aspect ratio of 4:1 and a depth of 800 μm were successfully fabricated. Furthermore, the effects of different scanning strategies on the bottom surface roughness of the gutter were examined. A gutter with a depth of 800 μm and a bottom surface roughness of Sa 1.13 μm was prepared using a cross-scan strategy, and a through-hole with an inlet diameter of 1.1 mm and an outlet diameter of 1 mm was fabricated using a circular-drilling strategy. Ultimately, this work demonstrates the direct fabrication of a complete diamond microchannel heat sink assembly.
科研通智能强力驱动
Strongly Powered by AbleSci AI