$$\rightleftharpoonup{xx}$$
$$\longleftharp{xx}$$,
$$\longrightharp{xx}$$,
In nature, water striders possess remarkable ability to jump or glide easily and rapidly on the water surface with the help of the slender and nonwetting legs1,2,3,4,5, but seldom move slowly, which is unlike the terrestrial insects. The hierarchical structure of water strider stabilizes the superhydrophobic state, which renders dramatic reduction in contact area and adhesion force between water and the leg6,7,8,9. However, the hydrodynamic advantages of the quick disengagement of water striders from water surface remain poorly interpreted10,11,12.
The process of jumping from the water surface is mainly divided into three stages13,14,15,16. At first, water striders push the water surface downward with the middle and rear legs to convert the biological energy into the surface energy of the water until sinking to the maximum depth, which enable the insect to initialize the jumping direction and determine the detaching velocity. Followed by the ascending stage, the insect is pushed upward by the capillary force of the curved water surface until reaching the maximum velocity. In the final disengagement stage, the water strider continues to rise up by inertia until breaking away from the water surface, but the velocity is largely reduced due to the adhesion force with the water, which has principal influence on the energy consumption of the water strider. Hence, this protocol is proposed to measure the adhesion force at different take-off velocities in the disengagement stage and explain the distinct characteristic of fast moving.
There have been many studies to explore the adhesion force of water striders when propelling from water surface. Lee & Kim theoretically and experimentally confirmed that the adhesion force and energy required lifting the water strider's legs decreased dramatically when the contact angle increased to 160 degrees17. Pan Jen Wei designed a hydrostatic experiment to measure the adhesion force by the TriboScope System, which was found to be 1/5 of its weight 18. Kehchih Hwang analyzed the quasi-static process of the legs detaching from the water with a 2D model and found the superhydrophobicity of the legs played a significant role in reducing the adhesion force and energy dissipation19. However, the measurement of the adhesion force in previous studies was just in condition of a quasi-static process, which was unable to monitor the adhesion force changes during the fast jumping.
In this study, we designed a dynamic force measurement system using polyvinylidene fluoride (PVDF) film sensor and other adjuvant instrument. Compared with other piezoelectric materials, PVDF is more suitable for measuring the dynamic microforce with higher sensitivity20,21,22. By integrating the PVDF film sensor into the system, the real-time adhesion force could be detected and processed when the leg was pulling up from water surface23,24,25.