Abstract
Structural color—a widespread phenomenon observed throughout nature is caused by light interference from ordered phases of matter. While state-of-the-art nanofabrication techniques can produce structural organization in small areas, cost-effective and scalable techniques are still lacking to generate tunable color at sub-micron length scales. In this work, structurally colored hydroxypropyl cellulose filaments are produced with a suppressed angular color response by 3D printing. The systematic study of the morphology of the filaments reveals the key stages in the induction of a two-degree hierarchical order through 3D printing. The first degree of order originated from the changing of the cholesteric pitch at a few hundred nm scale via chemical modification and tuning of the solid content of the lyotropic phase. Upon 3D printing, the secondary hierarchical order of periodic wrinkling is introduced through the Helfrich–Hurault deformation of the shear-aligned cholesteric phases. In single-layered filaments, four morphological zones with varying orders of wrinkles are identified. Detailed morphological characterization is carried out using SEM to shed light on the mechanism of the wrinkling behavior. Through this work, the possibility of modifying the wrinkling behavior is demonstrated and thus the angle dependence of the color response by changing the printing conditions.
Original language | English |
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Article number | 2205506 |
Journal | Small |
Volume | 19 |
Issue number | 8 |
Early online date | 11 Dec 2022 |
DOIs | |
Publication status | Published - 22 Feb 2023 |
Keywords
- 3D printing
- biomimicry
- cholesteric liquid crystals
- hierarchical photonic structures
- hydroxypropyl cellulose
- shear-induced deformation
- 3D printers
- Biomimetics
- Cellulose
- Cholesteric liquid crystals
- Color
- Cost effectiveness
- Nanotechnology
- 3-D printing
- 3D-printing
- Biomimicry
- Cholesteric liquid-crystal
- Cholesteric phasis
- Hierarchical photonic structure
- Hydroxypropyl cellulose
- Photonic structure
- Shear-induced
- Shear-induced deformation
- Chemical modification
- Cost Effectiveness
- Filaments
- Hydroxypropyl Cellulose
- Light
- Phases
- Printing