A three-dimensional (3D) holographic focal volume engineering method is proposed and employed for advanced multiphoton polymerization. A large number of foci are closely positioned in space according to a designed geometry, avoiding undesired interference effects by phase engineering. Through all-optical micro-displacements in space, the discrete foci bundle leads to the realization of complete 3D arbitrary structures. The microstructures are fabricated by direct laser writing without additional optical or mechanical motion support. We report a 20-times faster fabrication time in comparison to point-by-point laser polymerization techniques.
Chemistry in light-induced 3D printing
Improved two-photon polymerization through an optical fiber using
Ultrafast 3D nanofabrication via digital holography
Versatile applications of three-dimensional objects fabricated by
Patterning High to Low Heterogenous Fluid Shear Stress Landscapes
Overcoming delamination in two-photon lithography for improving
Woodpile photonic crystals: (a) the whole structure, (b) detail
Light-sheet 3D printing via non-degenerate two-step absorption
Researching Emerging micro-additive manufacturing technologies
Recent progress in functionalized plastic 3D printing in creation
Researching Micro-Nano 3D Printing Based on Photopolymerization
Researching Emerging micro-additive manufacturing technologies
Rapid, continuous projection multi-photon 3D printing enabled by
Holographic Femtosecond Laser Parallel Processing Method Based on
4D printing of light activated shape memory polymers with organic