10 Material To Harvest WaterNamib Desert Beetle
Rain has not blessed the sands of the African Namib Desert. The land is scorching, yet a merciful cover of light fog rolls across the sand dunes each morning. It is the perfect home for the Namib Desert beetle. When water droplets from the fog collect on the beetle’s shell, water-repellent ridges channel the drops toward its head. The shell is dotted with small, hydrophilic nubs. As moisture accumulates, the droplets get bigger until they slide toward the beetle’s mouth, effectively quenching its thirst. Engineers from the Massachusetts Institute of Technology have borrowed this skill to create a material that can harvest water from thin air. Made of glass and plastic and riddled with the same tiny ridges, the spongelike substance is cheap and can be built simply by printing hydrophilic dots onto sheets of hydrophobic materials. If a camping tent mimicked this surface, it would be able to harvest a day’s worth of water every morning. Furthermore, the insect’s high tolerance of heat suggests infrared reflectors on its shell, which can aid in fields that need heat-resistant equipment such as rocket design.
9 Living MicrorobotsLamprey
Things would certainly be a lot easier if doctors could get inside your body and pinpoint the exact cause of pain or disease. Imaging technology is often grainy with low resolution, while MRI machines are bulky and expensive. With the coming invention of robots that are tiny enough to swim inside your bloodstream, medicine will become a lot easier. Cyberplasm is a robot that is “alive” in a sense. Loaded with sensors taken from actual mammalian cells, it responds to chemicals and light in the same way that a living organism would. Complete with eye and nose sensors, the miniature robot contains an artificial, glucose-powered nervous system that records stimuli, which is converted into electrical signals in the same way that an actual brain functions. Cyberplasm is modeled after the lamprey, a type of parasitic fish with a long, tubelike form. This animal possesses a simple nervous system that is easy to mimic and build into a robotic body. In time, the lamprey robot may be cruising inside your body to search for tumors, blood clots, or chemicals.
8 Robotic ArmElephant
Composed of over 40,000 muscles, elephant trunks are as nimble as human hands, able to pick apples from a branch or rip an entire tree out of the ground. Their versatile design has also inspired a robotic arm. The German company Festo has developed the Bionic Handling Assistant, an appendage that can be used to alter handling technology for human-machine cooperation. Wielding four metallic claws, the robot learns just like a human baby would—through trial and error. By continually reaching for and grabbing objects, it works out which muscles to move. The robot is able to memorize changes in its position through adjustments in pressure within the tubes that feed its artificial muscles. Made of polyamide, this structural material is strong enough to lift heavy weights yet agile enough to perform delicate procedures, such as picking up an egg. The trunk proves to be a benefit for factories, laboratories, and hospitals, where it provides additional handling for human-directed projects.
7 Bullet TrainsKingfisher And Owl
When they exit a tunnel, Japan’s extremely fast bullet trains create a deafening “tunnel boom” due to the shape of the train’s nose. By pushing the air at high speeds, it produces a wall of wind that creates a racket and wastes fuel by slowing down the train. The solution? Take some advice from the birds. Kingfishers boast a streamlined beak that makes fishing more practical. Thanks to the pointed shape of its nose, the bird is able to dive into streams without a splash. The beak reduces impact by allowing the water to flow past the beak instead of being pushed in front of it. Eiji Nakatsu, an engineer and bird-watcher, altered the bullet train’s rounded nose to mimic the design of a kingfisher’s bill. Now the train is able to run at 300 kilometers per hour (185 mph) with reduced energy consumption and air resistance. Additionally, thanks to the elusive owl, the thunder-like noise was also dampened. The nose was altered to fit the design of the owl’s feathers, which are quiet enough to evade even the wariest of mice.
6 Squishy RobotsOctopus
Who said that robots have to be hard and metallic? A team of researchers from Italy discovered the advantages of an octopus’ squishy body. With the abilities to swim, hold objects, and crawl, the octopus robot uses a lot less computing power to function. Instead of moving in mathematically predictable ways like hard-bodied machines, octopus robots shrink, undulate, and curl. They lack rigid limbs and fixed joints, which is a benefit. Other robots modeled after solid skeletons require careful programming and other work to keep them from smacking into objects. They also have a tendency to become erratic, even dangerous, around humans and new terrain. Soft robots are much safer. They can twist themselves into new shapes and adjust well to their surroundings. With such forms, it is possible for them to rescue trapped people, interact with us, and function with no previous programming.
5 Cyborg FlowersRose
Did you know that roses can conduct electricity? Magnus Berggren and his team of researchers in Sweden were able to create this power by threading minute wires through the plants’ systems. After soaking the roses in an organic polymer solution, the rose bark was peeled back to reveal the tiny polymer “wires” snaking through the stems. They later proved to be electronically conductive. This method made it possible for the researchers to control the physiology of the roses, such as not allowing the flowers to bloom before an oncoming frost or helping to prevent drought. These modifications don’t go into the fruits or seeds. Although permanent changes can negatively impact an ecosystem, this invention can easily be switched on or off.
4 Germ-Repellent CathetersSharks
With its sleekness and durability, sharkskin is useful for all sorts of things—from swimsuits to shoes. What we didn’t expect, however, was catheters. Germs are a worry in every hospital. With so many people walking in and out, it’s no secret that surfaces can easily become coated with germs, spreading disease from one patient to the next. Engineer Tony Brennan discovered that nothing is cleaner than sharkskin. The surface is riddled with tiny carpets of toothlike scales that prevent slime, algae, and barnacles from latching onto the sharks’ bodies. Fortunately, sharkskin will also stop disease-causing bacteria such as E. coli. Sharklet is a company that is taking advantage of this concept. So far, it’s working. Their next step is to invent catheters made of sharkskin, which could help prevent a common source of infections.
3 Vaccine, DNA, And Stem Cell PreservationResurrection Plants, Tardigrades, And More
Using extreme hibernation, resurrection plants, a species of desert moss that dries out in intense temperatures, “die” and appear to be dead for years, even decades. But once the rains return, the plants easily become lush and green again. Tardigrades, microscopic water bears, are also one of the toughest animals on Earth. They have been hurled into outer space, exposed to extreme temperatures like absolute zero and 150 degrees Celsius (300 °F), and forced to endure radiation and go years without water. In response, the water bears shrivel up. Then they awaken, rehydrated, when their surroundings are favorable again. Brine shrimps, nematodes, and baker’s yeast are just a few others that use similar hibernation techniques. During these trials, the organisms merely replace all the water in their bodies with sugar. As the sugar hardens into glass, the organisms enter a state of suspended animation. While this method can surely kill humans, it is still good news for us: Vaccines, DNA, and stem cells can now be preserved for a longer period of time. Each year, two million children die from diseases that are easily preventable. Vaccines perish quickly in hot climates, but this sugar preservative hardens into microscopic beads within the vaccines, extending their shelf life to years.
2 Robot That Leaps On WaterWater Strider
Pond-skimmer insects are able to walk on water thanks to the “skin” that covers every body of liquid. Known as surface tension, the molecules stick together in a force known as cohesion. A lightweight robot has been constructed that leaps, rather than walks, on water. This robot is soft-bodied and weighs just 68 milligrams. Although engineers have already designed bots that are able to walk on water, this one is unique because it can jump on the surface of the water without sinking in. Researchers were able to do this by observing water striders. These insects accelerate their legs gradually, not letting go of the water until it is time to jump. They exert the right amount of force, keeping the surface tension unbroken and whole. Borrowing this tactic, the robot gradually applies enough torque to launch but does not go over the limit of the water’s “skin.” This action mimics the movement of a flea’s leg and can leap to an impressive 14 centimeters (6 in). This miniature bot may prove useful in surveillance and rescue operations.
1 Better X-Ray VisionLobster
X-rays are difficult to work with, which is why the X-ray machines at airports are so bulky. However, scientists are now copying a technique used by lobster eyes to gain better X-ray vision. Instead of refraction, or the bending of light by a lens, lobsters see using reflection. Their eyes are covered in squares, similar to flat mirrors, which reflect light at precise angles to form pictures from any direction. This design proves useful to astronomers, who yearn for telescopes that can focus X-rays from certain areas in space. While an ordinary mirror would only allow X-rays to pass through, the shapes of the lobster’s eyes are used to create arrays of tiny, square, hollow tubes made of lead glass. Curved into eyelike spheres, the material reflects X-rays and is packed into telescopes. These crustaceans have inspired other inventions as well, such as microchips and the Lobster Eye X-ray Imaging Device, a “flashlight” that can see through steel walls 8 centimeters (3 in) thick. When the device sends out a string of low-power X-rays through a wall, a few bounce back off the objects on the other side. These signals are funneled through the tubes and create images just like the lobsters’ eyes do. This invention may prove important in locating stolen or illegal goods.