Abstract
AbstractAn approach is presented to align the direction of liquid crystal networks or elastomers in situ during multi‐photon laser printing for each voxel in three dimensions by applying a quasi‐static electric field with variable orientation. This approach enables the making of 3D micro‐heterostructures operating under ambient conditions that show large‐amplitude elastic actuation, with temperature serving as the stimulus (“4D microstructures”). The approach involves two novelties. First, a dedicated sample cell with a variable height suitable for laser printing is introduced. It is based on optically transparent electrodes and allows to apply arbitrary electric field vectors in three dimensions, for example, parallel or normal to the substrate plane. Second, a variable optical phase plate combined with a pivotable half‐wave plate warrants a single well‐defined laser focus for nearly all possible quasi‐static electric field vectors. Without the latter, one generally obtains two spatially separated laser foci, an ordinary and an extraordinary one, due to the optical birefringence of the medium induced by the alignment of the liquid crystal director via the applied quasi‐static electric field. The versatility of the approach is illustrated by manufacturing and characterizing several exemplary architectures.
Highlights
The actuation of liquid crystal networks (LCN) is based on a phase transition, which brings the system from a low-temperature low-entropy phase, in which the individual liquid crystal molecules are aligned with respect to each other, to a high-temperature high-entropy phase in which the molecules are randomly oriented
We present our strategy to align the director of a liquid crystalline (LC) ink during multi-photon 3D laser printing via electric fields to obtain LCN structures with a spatially varying director
We have shown how to realize sufficiently homogeneous quasi-static electric fields of arbitrary direction in situ during the printing process to align the local director of the LC ink
Summary
We present our strategy to align the director of a liquid crystalline (LC) ink during multi-photon 3D laser printing via electric fields to obtain LCN structures with a spatially varying director. We take the substrate with the printed structure attached to it and wash away the insufficiently polymerized liquid ink to obtain a 3D structure with a spatially varying director. This overall process requires that we are able to induce homogeneous electric fields within the region where the polymerization happens. Thereby, the superscript always labels the intended average direction of the field vector
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