A closer look at the wings of the male "Cynandra opis" butterfly reveals the microstructures of two lattice layers stacked perpendicular to each other. This ‘crossed double-grating’ interacts with light to create blue iridescence. The structural colours are an inspiration for 3D printing bright, high-purity and iridescent colours. Image: ETH Zurich
In nature, colours often result from the interaction of light with periodic micro- or nanostructures. Using Nanoscribe’s 3D printing technology, scientists around the world are investigating various strategies for producing structural colours. Inspired by the "Cynandra opis" butterfly, bigrating structures were fabricated by Two-Photon Polymerization. These structures produce colours of high purity over the entire visible range. Researchers also succeeded in 3D printing various shapes on the microscale that exhibit structural colours.
There is a strong interest in studying structural colour because in nature this effect occurs in a variety of forms. For example, butterfly wings are of particular interest due to their vibrant and iridescent structural colours. Unlike synthetic dyes and pigments, structural coloration offers advantages such as brightness, usually angle dependence, stability in terms of fade resistance and its environmental friendliness. Nanoscribe’s additive manufacturing technology based on Two-Photon Polymerization (2PP) enables the precise and reliable fabrication of nature-inspired structures that generate structural colours. Exploiting the outstanding spatial resolution of 2PP-based 3D printing down to the submicron range, the dependence of structural colours on various structural parameters can be experimentally investigated.
Mimicking butterfly colours with bigrating structures
The wings of the "Cynandra opis" butterfly generate blue iridescence. Inspired by this, scientists at the ETH Zurich led by Professor Andrew deMello produced bigrating nanostructures that mimic those contained in the butterfly’s wings. The 3D structures consist of two grid layers stacked perpendicular to each other, also known as a ‘crossed double-grating’ structure. Such a structure consists of two diffractive planes, with an array of ridges forming the first, and a perpendicular array of ridges below this forming the second. These orthogonal planes can diffract light in both the x and y directions. The combined effects of diffraction and interference generate coloration.
Planar colours with 3D-printed nanostructures
Based on these observations, the scientists designed and 3D-printed bigrating nanostructures with different parameters. In this way, they were able to investigate the influence of incident angle, period and height on the structural coloration. Variations in the feature period and/or height of the ridges affected both hue and colour purity. The transparent substrate used to print the structures allowed the researchers to illuminate the structures from behind to create the coloration effect under different incident angles. Variations in the grating period between the first and second planes, while keeping the grating height constant, resulted in the generation of a full range of colour pixels in a plane covering the visible spectrum. This type of bigrating structure was used to print a meter-sized image scaled down as a thumbnail image with millimeter dimensions and micrometer pixel size. Such multicolour structures are likely to find applications, for example, in digital 3D displays, colour filtering and high-density data storage such as in micro image displays.
3D shapes with structural colours
Moving from planar structural coloration to 3D objects that reflect structural colours is still a challenge. However, structural colours in 3D exploit the freedom to shape, control and display colours beyond the limitations of their 2D counterpart. Woodpile photonic crystals are promising structures that can be used as building blocks to form 3D shapes that display structural colours. However, these colours are generated when woodpile photonic crystals (WPC) are illuminated from the top and to achieve visible stop bands along the stacking direction, structural resolutions below 500 nanometers in all spatial directions are required. Manufacturing these structures with direct laser printing is challenging. Structural resolution can be improved, for example, by using advanced systems and novel materials or by post-processing steps such as heat shrinking
2PP-based printing of 3D structural colours
Researchers from the Agency for Science, Technology and Research A*STAR in Singapore, the Singapore University of Technology and Design and the Nanyang Technological University collaborated on a new strategy for using woodpile photonic crystals to create 3D structural colours: They investigated theoretically and experimentally the woodpile photonic crystals band structures under lateral illumination. A one-step printing process that avoids post-processing steps and the need to print subwavelength lattice constants was used to fabricate the WPCs.
Using Nanoscribe’s Two-Photon Polymerization, it was possible to fabricate a wide range of WPCs with varying in-plane (from 750 to 1,300 nanometers) and out-of-plane (from 900 to 1,400 nanometers) pitches. The height of the rods is 380 nanometers while the width is 130 nanometers. With this very small rod width, the WPCs generate high reflectance of bright structural colours, reaching up to 50% reflectance. This approach resulted in WPCs that reflected a wide range of colours, from blue, cyan, green, green-yellow, yellow, to red and purple. The vivid colours generated by these structures cover more than 85% of the sRGB colour space and exhibit excellent colour purity.
Tunable coloured 3D shapes
The researchers also validated the printing of arbitrary 3D shapes with coloration. They 3D-printed the Merlion, the iconic mascot of Singapore, and a 3DBenchy model, known as a benchmark for 3D printing performance. These 3D shapes are colourful, demonstrating the ability to tune the colours of different parts of the 3D shapes. Precise colour tuning at the voxel level was achieved by simultaneously changing in-plane and out-of-plane pitches even in intricate geometries. The colours reflected by these structures enable both gradual and abrupt colour changes. These findings will open up new applications for 3D freeform structural colours in fields such as coloration-based sensors, colour displays, light emitting devices and anti-counterfeiting applications.
Interested to read more about how Two-Photon Polymerization is used to print structural colors? Here you will find the full articles on Bioinspired "Cynandra opis" butterfly’s structural colors and 3D structural colors by 3D-printed woodpile photonic crystal