We just received a new record for his & # 39; fastest movement of Earth in animals


Even the smallest habitats can make the bigger campaigns. The movement of the fastest number of animals in the world is now an ant that is not larger than your roof.

Ominously named Dracula Dracula (Icon for Mystrium camillae), this uncontrollable species is rigorous and misleading, a subterranean predator that enjoys it; Blood is cleansed from its own indirect larvae in uses known as "uncontrollable cannabis".

It's also bad soon. A new study has found that the bugs of these rare and mysterious species can stop five thousand times faster than sunlight.

Mystrium 1 002(Royal Society of Open Science)

Using a high-speed camera, scientists have a & # 39; Smithsonian has now captured this incredible move in action for its & # 39; first time.

The procedure works as a type of bend, but at a long distance, a thousand times faster than the human hands that are capable.

By pressing all its windows together, the pressure of the # Between the construction of the media, until it breaks up, by releasing one of the mandables until it's done; crossing the other side.

From beginning to end, the action generates 0.000015 seconds, and # 39; ranging from zero to about 320 km / h (198 meters) in a block of weather.

This special feature of Dracula's drama now has a gold medal for the fastest known animal device and the ever-known ever-known biological movement.

11 December 2018 09 18 14(Royal Society of Open Science)

The species Icon for Mystrium has been referred to as "the most secretary group within the Dracula expert", and scientists are not sure why this funny surname has moved in particular.

Although, in the kingdom of animals, when it comes to capturing an animal and its; avoiding predators, a very important pace. Today, the fastest known movements are based on hunting and protection, and are usually monitored in artrapods such as mantis, cask-chromag, crabs and wind nose.

Among these creatures, energy is stored up in the muscles and then released through a cycle that allows the energy to be spread through something of a severe spring. By including quilts and fountains, these animals will be saved from a & # 39; doing work over their muscles, and this allows creatures such as the Dracula ant; Provision for food and their own protection against predators in the most effective way possible.

Even compared to other trap-jaw species, however Icon for Mystrium Dracula ant reigns supreme. At this time, we know at least six sets of berries that have more powerful heaters, but Icon for Mystrium camillae There is a special morphology that makes it especially fast.

Unlike other edges with trap-jaws, these mandibles will begin to start from a closed position and then click on. crossing each other. What's larger, the spring and latch tools that allow copy to be closed are enclosed inside their own adults.

Screen Shot 2018 12 11 at 9.26.28 m(Royal Society of Open Science)

This unique structure may be the one that gives such a distance to this generation. In trap ants like the Odontomachus and Myrmoteras genera – where the spring, circulation and incentive structures are split – it will take more than sixty-three times for the shutdowns. And even at the fastest speed, this motion is still thirty times faster than that Icon for Mystrium camillae possible.

Writers' authors believe that these distinctive habitats that have been created alongside the suburban habitat of this side may be – in tropics in south-eastern Asia and Australia – where there is no choice of choice.

"Mystrium's artificial and nesting practices are also restricted to restricted tunnels in logs and soils, and this may be welcomed by this type of expansion system where the device can not be used, It is widely opened as seen in trap-jaw berries that largely contribute to open space provision, "the authors propose.

But we can not be sure yet. These creatures are like a buried treasure, and further research is needed if we want to find out why they have developed such links.

This study was published in the # 39; Open Science to Royal Society (no link is still valid at the time of publication of this article).

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