3D micro-structures for rarefied gas flow applications manufactured via two-photon-polymerization

In this work, the two-photon-polymerization (TPP) fabrication technique was employed to manufacture three-dimensional (3D) micro-structures suitable for confined rarefied gas flows. Four different micro-tubes of sim-ple geometry have been tested in vacuum conditions. The geometry of the micro-tubes was characterized via a focus-variation 3D optical measurement microscope, a digital microscope , an X-ray mu-tomography. Mass flow rate measurements of pressure-driven rarefied gas flows of nitrogen in slip and transition regimes were compared to theoretical values obtained via the kinetic theory of gases. The experimental measurements were realized via the constant volume technique. The good agreement obtained between experimental and numerical results proves the feasibility of using this fabrication technique to create well controlled 3D shaped microsystems for rarefied gas flows applications.

Automated summary

The two-photon-polymerization (TPP) fabrication technique was used to create three-dimensional micro-structures for rarefied gas flows. The geometry of the micro-tubes was characterized using various measurement techniques. Experimental measurements of nitrogen gas flow rates were compared to theoretical values, and the results showed good agreement. This study demonstrates the feasibility of using TPP fabrication technique to create well controlled 3D microsystems for rarefied gas flows applications.