India's Living Root Bridges Could Be The Future of Green Design

Posted by Martina Birk on Sunday, April 14, 2024

Meghalaya, India's bridges made from living tree roots are as long as 164 feet and can carry dozens of people at a time.

Living root bridge in the Meghalaya Plateau, India.JAYANTA KHAN/IndiaPictures/Universal Images Group via Getty Images This living bridge spans a 65 foot wide stream in Cherrapunji‎, Meghalaya, India. Pallava Bagla/Corbis via Getty Images A young and a slightly older aerial root knotted together, which shortens and tightens them. Later, the roots will grow into one another at this point. Ferdninand Ludwig/TUM/EurekAlert Bridge over the Batang Bayang River in Pesisir Selatan in West Sumatra, Indonesia.Riau Images / Barcroft India / Barcroft Media via Getty Images A living root bridge being developed by ficus elastica strands guided along a halved Areca Palm trunk in Nongriat Village, India.elbowmacaroni/Wikimedia Commons Double living root bridge in Padu Village, Meghalaya, India.Anselmrogers/Wikimedia Commons This bridge is constructed by allowing the roots of Banyan trees to grow together and mature.ashwinkumar/Flickr Bridge in Cherrapunji, India. cristic/Flickr This bridge in Nongriat village, India is estimated to be 200 years old, an example of a bridge started by unknown ancestors. Nature Research Foot stones have been laid on the surface of this bridge.ashwinkumar/Flickr The longest known example of a root bridge at 164 feet. Rangthylliang, India..Anselmrogers/Wikimedia Commons Khasi villagers walk through a living root bridge near Mawlynnong in the northeastern state of Meghalaya, India. BIJU BORO/AFP via Getty Images Bridge near Cherrapunji, Meghalaya, India. AJAY SOOD/IndiaPictures/Universal Images Group via Getty Images A living root bridge near the village of Kongthong, India undergoing repairs.Anselmrogers/Wikimedia Commons The double-decker bridge in Meghalaya, India.cristic/Flickr Tall trees in Meghalaya.ashwinkumar/Flickr Bridge in the village of Nongriat. Arshiya Urveeja Bose/Wikimedia Commons In Burma Village, East Khasi Hills, a bridge is being developed by hand — without the aid of a scaffold. elbowmacaroni/Wikimedia Commons Locals training a root bridge using a wood and bamboo scaffold. Rangthylliang, East Khasi Hills, India.elbowmacaroni/Wikimedia Commons In Cherrapunji, India. Arindam Das/Wikimedia Commons A living bridge in Mawlynnong, India. cristic/Flickr Communities around this root bridge believe people bathing in Indonesia's Batang Bayang River just below the bridge have better luck at finding a romantic partner.Riau Images / Barcroft India / Barcroft Media via Getty Images Mawlynnong Village, Cherrapunji, India. Sutirtha Das wiki/Wikimedia Commons Ficus elastica roots have been trained across a pre-existing steel bridge, in the hope that eventually, as the steel elements fail, the roots will form into a usable living root bridge. elbowmacaroni/Wikimedia Commons The living root bridge at Mawlynnong on the outskirts of Shillong. Subhendu Sarkar/LightRocket via Getty ImagesBridge Over The Batang Bayang River India’s Living Root Bridges Could Be The Future of Green Design View Gallery

Imagine a bridge that actually grows stronger over time. A structure that's part of the environment rather than imposing upon it. These are what India's living root bridges are, and they could possibly help in our current global climate crisis.

Living root bridges are river crossings made from the sprawling aerial branches of certain trees. These roots grow around a framework of bamboo or other similar organic material. Over time, the roots multiply, thicken, and strengthen.

A 2019 study by German researchers examines living tree bridges in more depth than ever before — in the hopes of them being the next step toward eco-friendly structures in cities.

How Living Root Bridges Begin

Tree root bridges start humbly; a seedling is planted on each bank of the river where a crossing is desired. The tree most often used is the ficus elastica, or the rubber fig. Once the tree's aerial roots (ones that grow above the ground) sprout up, they are wrapped around a frame and guided by hand toward the opposite side. Once they reach the other bank, they are planted in the ground.

Smaller "daughter roots" sprout and grow both toward the origin plant and around the area of new implantation. These are trained in the same way, woven to form the bridge structure. It can take as much as a couple of decades for a bridge to become strong enough to support foot traffic. But once they are strong enough, they can last hundreds of years.

The practice of growing living bridges is widespread in the Indian state of Meghalaya, though there are a few scattered around southern China and Indonesia as well. They are trained and maintained by local members of the War-Khasi and War-Jaintia tribes.

Living root bridges are a marvelous marriage of engineering, nature, and design.

Diving deeper into the science of how these trees grow and interlock, the German study points out that aerial roots are so strong because of a special kind of adaptive growth; over time, they grow thicker as well as longer. This allows them to support heavy loads.

Their capacity to form a mechanically stable structure is because they form inosculations — small branches that graft together as bark wears away from the friction of the overlap.

Age, Location, And Cultivation

Many living root bridges are hundreds of years old. In some villages, the residents still walk bridges that their unknown ancestors built. The longest tree bridge is in India's Rangthylliang village and is just over 164 feet (50 meters). The most established bridges can hold 35 people at once.

They serve to connect remote villages and allow farmers to access their land more easily. It is an essential part of life in this landscape. Tourists are also drawn to their intricate beauty; the largest ones draw 2,000 people per day.

Tree root bridges withstand all the climate challenges of India's Meghalaya plateau, which has one of the wettest climates in the world. Not easily swept away by monsoons, they're also immune to rust, unlike metal bridges.

"Living bridges can thus be considered both a man-made technology and a very specific type of plant cultivation," explained Thomas Speck, a professor of Botanics at the University of Freiburg in Germany. Speck is also a co-author of the aforementioned scientific study.

Another co-author of the study, Ferdinand Ludwig, is a professor for green technologies in landscape architecture at the Technical University of Munich. He helped map a total of 74 bridges for the project, and noted, "It's an ongoing process of growth, decay and regrowth, and it's a very inspiring example of regenerative architecture."

Future Use In Green Design

It's easy to see how living root bridges can help the environment. After all, planted trees absorb carbon dioxide and emit oxygen, unlike metal bridges or chopped wood. But how else would they benefit us, and how exactly can we implement them into larger cityscapes?

https://www.youtube.com/watch?v=9DilgkXDAkU

"In architecture, we are placing an object somewhere and then it's finished. Maybe it lasts 40, 50 years ...
This is a completely different understanding," says Ludwig. There's no finished objects — it's an ongoing process and way of thinking."

"The mainstream way of greening buildings is adding plants on top of the built structure. But this would use the tree as internal part of the structure." he adds. "You could imagine a street with a tree top canopy without trunks but aerial roots on the houses. You could guide the roots to where the best growing conditions are."

This would effectively reduce cooling costs in the summer, using less electricity.

There may not always be rivers to cross in the city, but other uses could be skywalks or any other structure requiring a strong support system.

The prospects are encouraging at a time when our environmental prospects are bleak. On Dec. 2, 2019, at the U.N. Climate Change Conference COP25, U.N. Secretary-General António Guterres warned that the "point of no return is no longer over the horizon. It is in sight and hurtling toward us."

Unless carbon dioxide emissions and other greenhouse gases are greatly reduced, temperatures could rise to twice the threshold set in the 2015 Paris Agreement (2 degrees Celsius above pre-industrial levels) by the end of the century.

Others say the year 2050 is the tipping point. The next generation of living root bridges could be grown and functional as soon as the year 2035.

It's not too late to begin – as long as we begin now.

Next, see firsthand the ravaging effects of global warming. Then be inspired by the world's ingenious animal bridges — crucial to helping preserve our wildlife.

ncG1vNJzZmiZnKHBqa3TrKCnrJWnsrTAyKeeZ5ufonyttdWipaBloqS8tXnBq6Cdn5Wo