Paratarsotomus macropalpis

Paratarsotomus macropalpis is a species of mite belonging to the family Erythracaridae. The mite is endemic to Southern California and is usually observed darting amongst sidewalks and in rocky areas. Earlier classified as belonging to genus Tarsotomus, it was reclassified in 1999, along with four other species, to genus Paratarsotomus. It is quite small—0.7 mm—but has been recorded as the world's fastest land animal relative to body length.

Discovery

A specimen was first collected by William A. Hilton from beneath stones in Claremont, California. It was classified and named as Tarsotomus macropalpis by Nathan Banks whose report in 1916 was

Speed record

The mite has been recorded at a speed of 322 body lengths per second. This is far in excess of the previous record holder, the Australian tiger beetle Rivacindela hudsoni, the fastest insect in the world relative to body size, which has been recorded at or 171 body lengths per second. The cheetah, the fastest land animal, which has been clocked at a peak of, scores at only 16 body lengths per second.
High speed photography was used to record the speed of the mite, both in natural conditions and in the laboratory. The equivalent speed for a human running as fast as this mite would be.
P. macropalpis have an acceleration of 7.2 m/s², compared to 6 m/s² for the horse, 10 m/s² for the greyhound and 13 m/s² for the cheetah. Its deceleration values are of 10.1 m/s².
Besides the unusually great speed of the mites, the researchers were surprised to find the mites running at such speeds on concrete at temperatures up to. This is significant because that temperature is well above the lethal limit for the majority of animal species. To withstand desiccation due to the high temperatures, the mites displays an extreme resistance to water loss. In addition, they are able to stop and change direction very quickly.
The discovery pushes the limits of what is known about the physiology of animal movement and the limits on the speed of living structures. This finding is considered by the research team as opening new possibilities in the design of robots and in biomimetics.