10.6084/m9.figshare.4888178.v1 Christofer J. Clemente Christofer J. Clemente Hanns Hagen Goetzke Hanns Hagen Goetzke James M. R. Bullock James M. R. Bullock Gregory P. Sutton Gregory P. Sutton Malcolm Burrows Malcolm Burrows Walter Federle Walter Federle Supplementary Figure S1 from Jumping without slipping: leafhoppers (Hemiptera: Cicadellidae) possess special tarsal structures for jumping from smooth surfaces The Royal Society 2017 jumping insects controllable attachment anisotropic friction adhesion biomechanics kinematics 2017-04-19 08:44:43 Journal contribution https://rs.figshare.com/articles/journal_contribution/Supplementary_Figure_S1_from_Jumping_without_slipping_leafhoppers_Hemiptera_Cicadellidae_possess_special_tarsal_structures_for_jumping_from_smooth_surfaces/4888178 Many Hemipteran bugs can jump explosively from plant substrates, which can be very smooth. We therefore analysed the jumping performance of froghoppers (<i>Philaenus spumarius,</i> Aphrophoridae) and leafhoppers (<i>Aphrodes bicinctus/makarovi,</i> Cicadellidae) taking off from smooth (glass) and rough (sandpaper, 30 µm asperity size) surfaces. On glass, the propulsive hind legs of <i>Philaenus</i> froghoppers slipped, resulting in uncontrolled jumps with a fast forward spin, a steeper angle and only a quarter of the velocity compared with jumps from rough surfaces. By contrast, <i>Aphrodes</i> leafhoppers took off without their propulsive hind legs slipping, and reached low take-off angles and high velocities on both substrates. This difference in jumping ability from smooth surfaces can be explained not only by the lower acceleration of the long-legged leafhoppers, but also by the presence of 2–9 soft pad-like structures (platellae) on their hind tarsi, which are absent in froghoppers. High-speed videos of jumping showed that platellae contact the surface briefly (approx. 3 ms) during the acceleration phase. Friction force measurements on individual hind tarsi on glass revealed that at low sliding speeds, both pushing and pulling forces were small, and insufficient to explain the recorded jumps. Only when the tarsi were pushed with higher velocities did the contact area of the platellae increase markedly, and high friction forces were produced, consistent with the observed jumps. Our findings show that leafhoppers have special adhesive footpads for jumping from smooth surfaces, which achieve firm grip and rapid control of attachment/detachment by combining anisotropic friction with velocity-dependence.