Jumping water striders know how to avoid breaking water surface

Using slow motion video recordings of jumping insects (attached here and also available on YouTube), Jae Hak Son, Sang-im Lee and Piotr Jablonski made detailed descriptions of leg movements of nearly vertical jumps of water striders. Based on these data, Eunjin Yang and Ho-Young Kim built a mathematical model to explain jumping mechanics. Using this model, the researchers predicted the jump-speed maximizing behavior of several water strider species with a range of body sizes and leg morphologies and verified the predictions with the actual data.

The study reveals that jumping water striders behaved as if they "knew" when the water surface may be broken. Normally, the midlegs and hindlegs of the water striders provide the main support without breaking the surface layer of water. Small dimples are visible under each leg because the water surface is pushed against the body weight. When water striders jump upwards, they push downward the water surface further and the dimples quickly become deeper and deeper. As long as the dimples are not broken, the legs are supported on the water surface and push the body upwards making the quick jump possible. But, if the legs move too fast and too deep, then the dimple is broken and therefore the support on the water surface is lost. This makes the jumps slower, and the escape from predators less effective. Using a mathematical model, the researchers calculated for a the range of insect body sizes and leg morphologies the critical leg speed beyond which the dimple is predicted to break. The actual leg movements of these species of different body weights and morphologies were JUST below this critical thresholds. Hence, the insects move their legs fast, but just not too fast, in order to maximize the jump speeds.

It is now yet known if this precise adjustment of leg movements is based on individual learning or innate or "hard-wired" ability.