1 min readA Colourful, Seaweed-Based Ink for 3D Printing
Richland, WA — Some artists are embracing 3D printing as a new medium, allowing them to create intricate 3D compositions that are difficult to produce in any other way. But the rigid, plastic-based materials used in many 3D printers require high heat for workability. Now, researchers reporting in ACS Omega have developed a colourful new ink for 2D and 3D art made of mica pigments in alginate, a sugar from seaweed that forms a stable gel without heat.
Although most 3D printers use petroleum-derived raw materials, alginate has also been explored as an inexpensive bioink. In water, the material forms a viscous gum that transforms into a robust hydrogel when cross-linked with calcium ions. But whereas plastics are available in many colours, alginate is almost colorless. Because colour is such a vital component of art, Anne Arnold and colleagues wanted to add mica powders to alginate to create a new, vibrant ink for 2D and 3D compositions.
The researchers prepared an 8% alginate solution in water and added one of eight different colors of mica pigments. The mica powders dispersed completely in alginate solutions –– creating vibrant, pearlescent colours. The researchers could control the consistency of the media by adding more or less of the calcium chloride crosslinker. The team demonstrated the new bioinks, which they call ArtSea Ink, by 3D printing 2D art of a firefly, with a glow-in-the-dark additive to depict its abdomen, and a 3D structure showing the anatomy of the human brain. The 3D structures were stable over a period of several weeks if kept in a neutral, 200 mM calcium chloride solution. Although the alginate art currently isn’t stable over the long term, this could actually be an advantage because the material, unlike plastic, will biodegrade quickly if discarded, the researchers say.
Article adapted from an American Chemical Society news release.
Publication: Pearlescent Mica-Doped Alginate as a Stable, Vibrant Medium for Two-Dimensional and Three-Dimensional Art. Arnold, AM et al. ACS Omega (July 14, 2021): Click here to view.