Planar and Homeotropic Liquid Crystal Alignment on 3D-Nanoprinted Layers and Microstructures

<p>Precise control of liquid crystal (LC) alignment is 5 essential for most LC-based applications and is typically achieved 6 using alignment layers that induce molecular orientation through 7 surface topography or chemical interactions. Although two-photon 8 polymerization (2PP)-based direct laser writing (DLW) has 9 previously been explored for fabricating such layers, existing studies 10 have largely focused on flat surfaces designed for patterned planar 11 alignment, where LC orientation is governed by surface top12 ography. Consequently, one of the key advantages of this technique, 13 which is the fabrication of arbitrary three-dimensional geometries 14 with nanoscale precision, has remained largely unexplored for LC 15 alignment. In this work, we investigate 2PP-based DLW as a 16 versatile fabrication platform for engineering LC alignment through 17 the combined use of surface topography, material chemistry, and three-dimensional geometry. We first demonstrate patterned 18 planar-homeotropic alignment on a single substrate by integrating topographical and chemical alignment mechanisms. The 19 alignment concept is then extended beyond flat surfaces to three-dimensional microstructures, including inclined prism-like 20 geometries, capillaries, and fully 3D-printed cells in which both alignment layers and spacers are fabricated in a single process. This 21 approach enables controlled twisted nematic configurations without the need for postassembly substrate alignment. Furthermore, we 22 show that arbitrary 3D-nanoprinted microstructures can be chemically functionalized with conventional alignment agents, providing 23 additional means of tailoring LC orientation. By combining the tunable optical properties of liquid crystals with the ability of 3D 24 nanoprinting to fabricate arbitrary three-dimensional architectures, this approach may enable the future development of 25 microstructures that serve specific functions while simultaneously acting as alignment components.</p>