摘要
A laser writing method is developed to fabricate porous structures on copper microchannel wall surfaces for enhanced microchannel heat sinks(MHSs). The formation feasibility together with its mechanism of such porous structures is explored by the comparison of dry and wet laser writing process, i.e., in both air atmosphere and under de-ionized water. Rectangular microchannels with ripples-like porous structures on the wall surfaces, which consisted of numerous micro-holes and micro-cavities,have been successfully formed in the dry laser writing process. Nevertheless, the microchannel wall surfaces were hardly altered in wet conditions. Besides, the effect of laser fluence on the formation of porous structures on the microchannels was also assessed in both dry and wet conditions. In dry laser writing process, the microchannel depth and surface roughness of wall surface increased monotonically, whereas the microchannel bottom width decreased continuously with increasing the laser fluence. On the other hand, the microchannel wall kept almost unchanged with smooth surfaces with increasing laser fluence in wet conditions.
A laser writing method is developed to fabricate porous structures on copper microchannel wall surfaces for enhanced microchannel heat sinks(MHSs). The formation feasibility together with its mechanism of such porous structures is explored by the comparison of dry and wet laser writing process, i.e., in both air atmosphere and under de-ionized water. Rectangular microchannels with ripples-like porous structures on the wall surfaces, which consisted of numerous micro-holes and micro-cavities,have been successfully formed in the dry laser writing process. Nevertheless, the microchannel wall surfaces were hardly altered in wet conditions. Besides, the effect of laser fluence on the formation of porous structures on the microchannels was also assessed in both dry and wet conditions. In dry laser writing process, the microchannel depth and surface roughness of wall surface increased monotonically, whereas the microchannel bottom width decreased continuously with increasing the laser fluence. On the other hand, the microchannel wall kept almost unchanged with smooth surfaces with increasing laser fluence in wet conditions.
基金
supported by the National Natural Science Foundation of China(Grant No.51775464)
the Science and Technology Planning Project of Guangdong Province,China(Grant No.2017A010104002)
the Open Fund of Hubei Key Laboratory of Mechanical Transmission and Manufacturing Engineering in Wuhan University of Science and Technology(Grant No.2017A01)
the financial support of Collaborative Innovation Center of High-End Equipment Manufacturing
