Multi-shape memory by dynamic elastocapillary self-assembly

Inspired by the synchronized beating of cilia, we show that the collective dynamics of hair-like fibers in a meniscus during fast drainage enables their self-organization into multiple topologies including complex shape inversions. By draining liquid from triangular-base hair bundles, we demonstrate their transformations into concave hexagons, rounded triangles, circles and inverted triangles. These topologically distinct shapes are quenched collective mode shapes of the beating hair each corresponding to specific drainage rates of the liquid, and cyclic shape re-transformations can be simply stimulated by repeated immersion and drainage. The various topologies correspond to multiple elastocapillary equilibria. Complex cellular materials with varying pore size and density can be obtained by changing the drain rates from hair assemblies. Due to its simple implementation and energy efficiency, these shape transformations can have applications ranging from three-dimensional lithography to smart multi-functional surfaces.