By Michael Patrick Rutter
School of Engineering and Applied Sciences
From the structure of DNA to nautical rope to distant spiral galaxies, helical forms are as useful as they are abundant in nature and manufacturing alike. Researchers at Harvard’s School of Engineering and Applied Sciences (SEAS), the Wyss Institute for Biologically Inspired Engineering, and the Radcliffe Institute for Advanced Study have discovered a way to synthesize and control the formation of nanobristles, akin to tiny hairs, into helical clusters and have further demonstrated the fabrication of such highly ordered clusters, built from similar coiled building blocks, over multiple scales and areas.
The finding has potential use in energy and information storage, photonics, adhesion, capture and release systems, and as an enhancement for the mixing and transport of particles. Lead authors Joanna Aizenberg, Gordon McKay Professor of Materials Science at SEAS, the Susan S. and Kenneth L. Wallach Professor at the Radcliffe Institute, and a core faculty member of the Wyss Institute; and L. Mahadevan, Lola England de Valpine Professor of Applied Mathematics at SEAS and also a Wyss Institute core faculty member, report the research in tomorrow’s edition of the journal Science.
“We demonstrated a fascinating phenomenon: How a nanobristle immersed in an evaporating liquid self-assembles into an ordered array of helical bundles. This is akin to the way wet, curly hair clumps together and coils to form dreadlocks — but on a scale 1,000 times smaller,” said Aizenberg.
To achieve the “clumping” effect, the scientists used an evaporating liquid on a series of upright individual pillars arrayed like stiff threads on a needlepoint canvas. The resulting capillary action — the wicking action or the ability of one substance to draw another substance into it — caused the individual strands to deform and to adhere to one another like braided hair.
“Our development of a simple theory allowed us to further characterize the combination of geometry and material properties that favor the adhesive, coiled self-organization of bundles and enabled us to quantify the conditions for self-assembly into structures with uniform, periodic patterns,” said Mahadevan.
By carefully designing the specific geometry of the bristle, the researchers were able to control the twist direction (or handedness) of the wrapping of two or more strands. More broadly, Aizenberg and Mahadevan expect such work will help further define the emerging science and engineering of functional self-assembly and pattern formation over large spatial scales.
Potential applications of the technique include the ability to store elastic energy and information embodied in adhesive patterns that can be created at will. This has implications for photonics in a similar way to how the chirally ordered and circularly polarizing elytral filaments in a beetle define its unique optical properties.
The finding also represents a critical step toward the development of an efficient adhesive or capture and release system for drug delivery and may be used to induce chiral flow patterns to enhance the mixing and transport of various particles at the micron and submicron scale.
“We have teased apart and replicated a ubiquitous form in nature by introducing greater control over a technique increasingly used in manufacturing, while also creating a micro-physical manifestation of the terrifying braids of the mythical Medusa,” said Mahadevan.
“Indeed, our helical patterns are so amazingly aesthetic that often we would stop the scientific discussion and argue about mythology, modern dreadlocks, alien creatures, or sculptures,” added Aizenberg.
Aizenberg and Mahadevan’s co-authors include Boaz Pokroy and Sung H. Kang, both in the Aizenberg Biomimetics Lab at SEAS. The research was supported by the Wyss Institute for Biologically Inspired Engineering at Harvard; the Harvard Materials Research Science and Engineering Center; and the Center for Nanoscale Systems, a member of the National Nanotechnology Infrastructure Network initiative.