Femtosecond laser micromachining of zirconia green bodies

Abstract

In this study, we developed micromachining processes using a femtosecond Ti: sapphire laser for zirconia green bodies, i.e., composites comprising zirconia particles and polymer binders. The laser ablation characteristics of the zirconia composites were analysed to optimise the process. In comparison with bulk zirconia, ablation of the zirconia green bodies occurred at lower fluences. In the high-fluence regime, laser irradiation directly ablated the zirconia particles, causing aggregation of resolidified particles. The ablated depth increased with fluence (F) and overlap number (N) initially, but saturated when F and N became larger. Microchannels with a minimum width of 4 μm were fabricated. The microchannel width decreased with decreasing fluence and overlap number. Microholes, microchannels and three-dimensional structures with a size of several tens of micrometres and aspect ratio of 5-15 were successfully fabricated using the zirconia composite. sensing/analysis with emphasis on laser micromachining, laser 3D printing of metal/semiconductor parts, modelling, simulation of high-power laser interaction with materials and microscale thermal sensing. He published numerous archival journal papers and won several awards, including the inaugural Kwangwon Award from KSLP and the Netzsch KSTP Thermophysical Properties Award. This paper is a revised and expanded version of a paper entitled 'Micromachining of zirconia greenbody using fs laser'