Researchers have discovered how to make a new kind of metamaterial reconfigure itself without tangling itself up in knots, opening up the possibility of a broad array of space applications. Metamaterials are a hot topic in engineering. These are materials inspired from biological systems. Many living structures start from simple, repeatable patterns that then grow into large, complex structures. The resulting structures can then have properties that the small subcomponents don’t. For example, individual bone cells or coral polyp skeletons aren’t very strong, but when they work together they can support huge animals or gigantic underwater colonies. One promising kind of metamaterial is known as a Totimorphic lattice. This lattice starts from a triangular shaped structure. On one side is a fixed beam with a ball joint in the center. An arm attaches to that ball joint, and the other end of the arm is attached to the ends of the fixed beam with two springs. Many of these shapes attached together can morph into a wide variety of shapes and structures, all with very minimal input, giving the Totimorphic lattice incredible flexibility. In a recent paper, scientists with the European Space Agency’s Advanced Concepts Team found a way to reconfigure Totimorphic lattices without having them tangle up on themselves. They discovered this using a series of computer simulations, creating an optimization problem for the algorithm to solve. With the algorithm in hand, they could then take any configuration of the lattice and change it to another in an optimal, efficient way. The researchers showed off their technique with two examples. The first was a simple habitat structure that could change its shape and stiffness, which could allow future astronauts to deploy the same kind of metamaterial to build a variety of structures, and reconfigure them as mission needs changed. The second example was a flexible space telescope that could change its focal length by adapting the curvature of its lens. This would enable a single launch, with a single vehicle, to serve a variety of observing needs. As of right now, this is all hypothetical. Totimorphic lattices don’t exist in practice, only as curious mathematical objects. But this research is crucial for advancing humanity into space. The cost and difficulty of launching materials into space mean that we need flexible, adaptable structures that are cheap to launch and easy to deploy. This research is yet another example of how we can draw inspiration from nature, in this case investigating the surprising properties of metamaterials, to bring ourselves into a future in space. The post A Flexible, Adaptable Space Metamaterial appeared first on Universe Today.