Plants and animals have evolved over billions of years to live in all sorts of harsh environments. Now scientists are looking to them for sustainable solutions to tricky design challenges.
Shark skin has inspired the design of new, antibacterial surfaces in places like hospitalsImage: Michael Weberberger/imageBROKER/picture alliance
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Nature has influenced many of the world's greatest inventions. The idea for Velcro fabric fasteners was sparked as its inventor was removing burdock burrs from his dog's fur after a walk. Airplanes, naturally, mimic a bird in flight. And microneedles have the mosquito to thank for a design that minimizes the pain of an injection.
Tasked with searching for a sustainable, proven solution to tricky engineering challenges, designers are increasingly allowing nature and their imaginations to take the lead. The field of biomimetics or biomimicry looks to structures and biological processes found in nature for inspiration.
"One of the common elements of humanity and throughout history and across cultures is imagination," said Robert Blasiak, a researcher at the Stockholm Resilience Center, which looks how to reconnect society with nature. "And I think biomimetics is an area where dreaming is required. It's one of the ingredients for making the whole thing work."
The tiny hooks on the burdock plant revolutionized the fashion industryImage: Rolf Poetsch/CHROMORANGE/picture alliance
Streamlining trains with birds on the mind
A classic example of biomimicry is the Japanese bullet train, the Shinkansen, first introduced in 1964. Traveling at a top speed of 320 kilometers (199 miles) per hour, the high-speed train network has revolutionized mass transit in Japan and provided a cleaner alternative to private automobiles.
Earlier designs weren't as sleek and aerodynamic as today's engines, resulting in vibrations and noise during travel — especially when the train would shoot through tunnels and leave behind a sonic boom.
Kingfishers dive into the water to catch fish, barely causing a ripple with their streamlined beaksImage: Paul Sawer/Avalon/picture alliance
In 1994, engineer Eiji Nakatsu was tasked with eliminating the explosive bang, vibration and pressure waves and develop a smoother ride. An avid birdwatcher, Nakatsu made changes to the train's design based on an owl's wing and the spindle-like body shape of an Adelie penguin.
To eliminate the sonic boom, he modeled the nose of the train after the kingfisher's long, tapered beak, which allows it to dive into water to catch fish with barely a splash. The booms stopped, and as a bonus, the trains were able to travel 10% faster and use 15% less electricity.
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Solar panels optimizing the sun's rays
As the world tries to move away from fossil fuels, solar photovoltaics are "becoming the lowest-cost option for new electricity generation in most of the world," according to the International Energy Agency.
To make them even more efficient, engineers took their cue from the wing of the rose butterfly, a cold-blooded insect native to Southeast Asia, which absorbs energy from the sun to stay warm. To do so, the creature has developed black wings marked with tiny holes only a millionth of a meter wide. These holes scatter light as it hits the dark surface, making it easier for the butterfly to use the sun's energy to heat up.
The wings of the rose butterfly are ideal for soaking up the sunImage: Thomas Marent/Mary Evans Picture Library/picture alliance
By incorporating similar holes in their designs, engineers have developed solar panels that are thinner and lighter. Not only that — they absorb more energy than traditional solar panels, according to the researchers.
Scientists at Princeton University were also inspired to improve solar panel efficiency by looking at leaf structures. They included microscopic folds in the panel's surface to channel light waves and increase electricity generation by nearly 50%.
"By adding these curves, we create a kind of wave guide," said biological engineering professor Yueh-Lin Loo, who was part of the research team. "And that leads to a greater chance of the light being absorbed."
Harvesting fog in the desert
Another insect that has influenced a sustainable solution is the Namib Desert beetle, which lives in southwestern Africa, one of the most arid places on Earth.
Through fog basking, the Namib Desert beetle is able to survive the arid conditions in southwestern AfricaImage: M. Harvey/WILDLIFE/picture alliance
By extending its long legs and leaning its bumpy body into the wind, this small black beetle can collect droplets of water from the morning fog. The droplets combine until they are big enough to roll down the beetle's body, and are then channeled into its mouth.
This evolutionary innovation has inspired designers to come up with a system that uses screens to collect water escaping from the plumes of cooling towers at industrial facilities, with the potential to save hundreds of millions of liters every year.
The shape of the beetle's bumpy shell has also been used to create a mesh-like material that can be unfurled to gather water from the air in arid regions worldwide.
Catching fog in Morocco
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Undersea inspiration
As researchers venture further into the world's largely unexplored ocean depths, they're uncovering design secrets that have allowed aquatic life to thrive for millennia. Take the humpback whale, for example, which is known for being extremely agile despite its size. It sports a series of bumps or ridges along the front edge of its fins, known as tubercles.
Experts in fluid dynamics, who previously thought that wind turbines had to be smooth and streamlined for optimal performance, realized these bumps create tiny vortices that reduce drag and noise and help the fin cut through the water.
For its size, the humpback whale is surprisingly acrobatic Image: Dave Hutchison/All Canada Photos/picture alliance
This revelation has led the way for new efficient designs for wind turbines, tidal turbines, airplanes, watercraft and surfboards.
Other, less mobile sea creatures have also contributed to sustainable design solutions.
Coral has a hard exoskeleton made up of calcium carbonate — essentially oxygen, carbon and calcium found in seawater. By imitating this process with captured CO2 from industrial plants, for example, the construction industry now has the possibility to make cement with a renewable, less wasteful method. At the same time, the process sequesters carbon emissions and prevents them from contributing to global warming.
Coral's hard exoskeleton is made up of oxygen, carbon and calcium found in seawaterImage: blickwinkel/imagesandstories/picture alliance
Seaweed and other aquatic plant life, meanwhile, have given marine researchers a way to avoid the toxic chemicals normally used to prevent marine algae, bacteria and barnacles from covering and contaminating boats and coastal industrial facilities.
The surfaces of these plants have evolved coatings to make it difficult for microorganisms to gain a foothold. Shark skin also has similar properties, with its rough surface proving inhospitable to bacteria. This has influenced the design of new, antibacterial surfaces in places like hospitals.
Creating an 'emotional connection' with nature
Innovative solutions aside, Blasiak of the Stockholm Resilience Center sees another benefit to using biomimicry in everyday life — specifically as a way of helping people make an emotional connection with another life-form or ecosystem that they don't understand.
"And if you have that emotional connection, it's also a basis for caring and for stewardship and wanting to be more sustainable in your relationship with these ecosystems," he said.
Sustainable buildings inspired by nature
Architects and designers have looked to nature for centuries — from Stonehenge to Beijing's Bird's Nest stadium. Known as biomimicry, the practice integrates sustainable natural solutions into our built environment.
Image: Frank Rumpenhorst/dpa/picture alliance
La Sagrada Familia, Barcelona, Spain
The landmark Roman Catholic cathedral by architect Antoni Gaudi has been a work in progress since 1882. Gaudi, whose style was heavily influenced by the natural world, was not a fan of the straight line. His magnificent structure features double twist columns that support the roof and draw the eye up to the stained glass skylights, which illuminate the sacred space with gold and green light.
Image: Frank Rumpenhorst/dpa/picture alliance
Forest canopy
Gaudi's work recalls the sun-dappled light that filters through a forest canopy. Visitors to the nave, the central area of the church, may feel like they're walking through a forest glade. His columns, which branch out to support the vault and roof, mimic the way trees distribute weight and as such are able to bear a greater load than traditional columns.
Image: Halil Sagirkaya/AA/picture alliance
Eastgate Centre, Harare, Zimbabwe
This office and shopping complex was Africa's first building to use passive ventilation. Built in the mid-1990s, it takes advantage of consistent daily temperature swings to cool and heat naturally. Fans draw in fresh air at ground level and push it up through hollow floors and vents to the roof, where warm air escapes. Thick brick walls, limited windows, shades and a pale facade keep things cool.
Image: Mick Pearce
Termite mounds
Pearce was inspired by the termite mounds that dot Zimbabwe's savannah. These huge structures, some as high as 9 meters (about 30 feet), are shaped to catch the breeze at the base and vent hot air out the top. Termites, which need to keep their body temperature at around 30 degrees Celsius (86 Fahrenheit), are constantly building new tunnels and blocking others to regulate heat and humidity.
Image: Julian Peters/Zoonar/picture alliance
30 St Mary Axe, London, UK
This iconic skyscraper has been a part of the London skyline since 2003. Designed by Norman Foster and more commonly known as The Gherkin, it also benefits from passive heating and cooling, along with a double-skin glass facade that helps insulate the offices and maximize natural light.
Image: Martin Sasse/DUMONT/picture-alliance
Venus' flower basket
The building's interior is open and spacious thanks to an exterior lattice structure. Diagonal braces provide support for the 180-meter (590-foot) tower — much in the same way a silica skeleton helps this glass sponge survive the ocean depths in the Pacific and Indian oceans. The Gherkin's ventilation system was also based on the way the sponge filters seawater for nutrients.
Image: Wikipedia/Public Domain
BIQ Algae House, Hamburg, Germany
A five-story apartment complex in northern Germany, built in 2013, has integrated living matter into its design. A " bioreactor facade" helps to provide shade and provides a form of renewable energy to power the building. Two south-facing sides of the building are mounted with 129 bioreactors, glass panels that form a vertical algae farm.
The algae — which enjoy a steady diet of liquid nutrients and carbon dioxide — bask in the rays of the sun and use photosynthesis to grow and fill the panels. They're harvested and stored in tanks in the building, then fermented at a nearby power plant and used to generate electricity. During the summer, the algae help shade the windows; slower growth in the winter provides more light.
Image: ChinaFotoPress/Getty Images
Milwaukee Art Museum, Wisconsin, US
Spanish architect Santiago Calatrava's addition to Milwaukee's premier art gallery, completed in 2001, is shaped like the prow of a ship — appropriate for its lakeside location. A massive sunscreen roof, composed of 72 steel fins, can open and close to provide shade. When fully extended, it has a wingspan of 217 feet (about 66 meters), comparable to a 747 jet.
Image: Shawn Thew/dpa/picture-alliance
Bird in flight
Calatrava wanted to reflect the urban and natural features of the setting, especially the passing boats and sails. The wings of the 90-ton roof take 3 1/2 minutes to open or close. The graceful movement is reminiscent of a bird taking flight.
Image: M. Varesvuo/WILDLIFE/picture alliance
Bird-friendly glass
Hundreds of millions of birds die each year running into transparent windows. Stickers attached to the glass can help but need to cover a large part of the surface — birds are used to flying through tight spaces. German company Arnold Glas has developed an insulating glass sheeting with a special ultraviolet reflective coating, nearly invisible to humans, that helps steer birds away from danger.
Image: Michael Probst/AP Photo/picture alliance
Spider's web
Most birds, like other animals, are able to see light in the ultraviolet spectrum because they have more rods and cones in their eyes than humans. It helps them to differentiate and avoid leaves as they fly through the treetops. And many spiders make their webs from silk that reflects UV light. It helps them attract insects — but sends birds flying in the other direction.
Image: picture-alliance/ZB
Exterior wall tiles
In the early 1990s, researchers at Japanese tile manufacturer Inax developed a silica coating that can be painted on exterior wall tiles to help keep them clean. Silica, a natural element found in soil, forms microscopic bumps on the tiled surface. Moisture in the air sticks to these bumps and attracts particles of soot, exhaust and other pollutants. When it rains, the buildings are washed clean.
Image: The Yomiuri Shimbun/AP Images/picture alliance
Snail shell
The researchers came up with the idea from observing snail shells, which have their own pattern of tiny bumps. The uneven surface creates tiny pools of water on the snail's shell, and contaminants float on these pools and are eventually flushed away by the next shower.
