Programming touch-me-not knot topologies for rapid and diverse leaping and flying motions
Summary
Miniature leaping robots are desired to perform fast, programmable, and versatile motions. In this study, we present our approach for harnessing the impulsive unknotting process triggered upon heating millimeter-sized knots made from Kevlar-reinforced liquid crystal elastomer (LCE) composite fibers. The LCE shell with twisted mesogens undergoes torsional deformation, generating an actuation force that overcomes friction, converting the stored elastic energy into kinetic energy for launchin
Content
# Programming touch-me-not knot topologies for rapid and diverse leaping and flying motions
*Published: 2026 Apr 23*
Miniature leaping robots are desired to perform fast, programmable, and
versatile motions. In this study, we present our approach for harnessing the
impulsive unknotting process triggered upon heating millimeter-sized knots made
from Kevlar-reinforced liquid crystal elastomer (LCE) composite fibers. The LCE
shell with twisted mesogens undergoes torsional deformation, generating an
actuation force that overcomes friction, converting the stored elastic energy
into kinetic energy for launching tall and rapid leaps with diverse posttakeoff
motions depending on the knot topology. By manipulating the bending-twisting
coupling and the unknotting numbers, we realize flipping, spinning, and
sequential gymnastic in-air motions. We further program posttakeoff flight,
including self-return and vertical descent by integrating a wing. Encoding
topology and anisotropy provides a rich design space to program soft robots for
rapid, agile, and highly efficient motions.
DOI: 10.1126/science.aed0434