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Volume 9

International Journal of Advancements in Technology

ISSN: 0976-4860

3D Printing 2018

March 19-20, 2018

March 19-20, 2018 | London, UK

2

nd

International Conference on

3D Printing Technology and Innovations

Two-photon polymerization: A femtosecond laser-based technology for additive manufacturing in

life sciences and microoptics

Sonke Steenhusen, Sebastian Hasselmann

and

Gerhard Domann

Fraunhofer Institute for Silicate Research ISC, Germany

3

D printing has been widely adopted on the macroscopic domain not only for rapid prototyping but also in manufacturing.

Several technologies ranging from the consumer market to an industrial level have been established. However, on the

micron-scale the possibilities to go into the third dimension are limited as the voxel sizes are dominated either by the diameter

of particles in powder-based additive manufacturing, by the thickness of the filaments, or the diameter of the droplets in

inkjet printing. These constraints can be circumvented when using femtosecond laser-based photopolymerization in liquid

photopolymers for creating 3D microstructures. Here, the solidification of the material is strongly confined to the focal

spot of focused laser pulses where the intensities are sufficiently high to trigger two-photon absorption. Hence, two-photon

polymerization (2PP) is an inherent 3D technology with voxel sizes down to 100 nm. The exposure strategy is similar as in

conventional 3D printing. The volume to be written is scanned in 3D, typically in a layerwise fashion. As in UV-lithography a

subsequent solvent wash (development step) is needed to get rid of the unexposed, and still liquid, resin. We will demonstrate

representative application examples from different fields of research. In life sciences 2PP-written 3D structures can be used as

substrates for cell cultivation, as they mimic the natural, porous environment which is required for proper cell expression. On

the other hand, 2PP can be used for diffractive and refractive microoptical elements which reveal excellent surface quality and

directly benefit from the freedom in design which only 3D printing can offer.

Biography

Sonke Steenhusen studied Physics in Würzburg and joined Fraunhofer Institute for Silicate Research ISC in late 2007 beginning his work in the field of additive

manufacturing. At the same institute he developed machines for two-photon polymerization and investigated the 3D patterning of hybrid polymers for applications in

microoptics. He is (co-)author of several papers in the field of 3D lithography. He is currently the Deputy Head of the Optics and Electronics Department at the same

institute which is dedicated to the development and processing of novel materials for optical and electronic applications. His research interest includes: additive

manufacturing, 3D printing, hybrid polymers, nanocomposites and two-photon polymerization.

soenke.steenhusen@isc.fraunhofer.de

Sonke Steenhusen et al., Int J Adv Technol 2018, Volume 9

DOI: 10.4172/0976-4860-C1-002