Few pulses femtosecond laser exposure for high efficiency 3D glass micromachining

Advanced three-dimensional manufacturing techniques are triggering new paradigms in the way we design and produce sophisticated parts on demand. Yet, to fully unravel its potential, a few limitations have to be overcome, one of them being the realization of high-aspect-ratio structures of arbitrary shapes at sufficiently high resolution and scalability. Among the most promising advanced manufacturing methods that emerged recently is the use of optical non-linear absorption effects, and in particular, its implementation in 3D printing of glass based on femtosecond laser exposure combined with chemical etching. Here, we optimize both laser and chemical processes to achieve unprecedented aspect ratio levels. We further show how the formation of pre-cursor laser-induced defects in the glass matrix plays a key role in etching selectivity. In particular, we demonstrate that there is an optimal energy dose, an order of magnitude smaller than the currently used ones, yielding to higher process efficiency and lower processing time. This research, in addition to a conspicuous technological advancement, unravels key mechanisms in laser-matter interactions essential in chemically-based glass manufacturing and offers an environmentally-friendly pathway through the use of less-dangerous etchants, replacing the commonly used hydrofluoric acid. (C) 2021 Optical Society of America under the terms of the OSA Open Access Publishing Agreement

Automated summary

Advanced three-dimensional manufacturing techniques are changing the traditional way of designing and producing sophisticated parts. Overcoming limitations like high-aspect-ratio structures is essential for unleashing the full potential. The use of optical non-linear absorption effects in 3D printing of glass has shown promising results in achieving unprecedented aspect ratio levels.