材料科学
飞秒
润湿
钻石
无定形碳
无定形固体
通量
激光器
热导率
光电子学
堆积
复合材料
晶体缺陷
成核
辐照
传热
金刚石立方
热的
碳纤维
纳米技术
蒸发
热阻
硅
金刚石材料性能
光学
界面热阻
作者
Yiling Lian,Zichen Zhang,Misheng Liang,Xun Zhao,Kefan Guo,J. L. Li,Zheling Li,Yang Lu
摘要
Diamond offers exceptional thermal conductivity for high-power and wide-bandgap devices, but poor wettability limits its application in liquid-cooling environments. In this work, femtosecond laser irradiation was used to modify the near-surface structure of single-crystal diamond, and the resulting effects on bonding configuration, lattice integrity, thermal response, and wetting behavior were systematically examined. Laser processing roughens the surface, produces an amorphous carbon layer, and introduces shock-related stress into the substrate. As the fluence increases from 3.77 to 19.39 J/cm2, the amorphous layer becomes thinner and less ordered, the amorphous–diamond interface becomes progressively more corrugated, and the underlying crystal evolves from exhibiting residual strain to containing dense stacking faults and point defects. The roughened surfaces and laser-induced sp2-bonded amorphous carbon improve wettability and facilitate bubble nucleation during boiling, while ultrafast reflectivity measurements show that defect accumulation suppresses carrier excitation and slows thermal relaxation. In line with these trends, the droplet evaporation time decreases from 8.357 s on the pristine surface to 6.745 s after irradiation at 3.77 J/cm2, whereas the times for the 7.97 and 19.39 J/cm2 surfaces increase to 6.935 and 7.890 s, respectively. These results demonstrate how laser-induced carbon structural modifications govern thermal transport and identify processing conditions that enhance wettability without severely degrading thermal transport performance, offering a promising route for engineering diamond interfaces for liquid-cooling applications.
科研通智能强力驱动
Strongly Powered by AbleSci AI