The Great Wall of China is being held together by ‘biocrusts’
Large swaths of the Great Wall of China are held together thanks to ‘biocrusts’, thin layers of organic materials that have helped protect the architectural marvel from erosion. Scientists made the discovery while analysing segments of the Great Wall of China, which spans more than 13,000 miles and was built over the course of many centuries, beginning in 221 BCE, as a way to protect the country’s empires from the outside world. During construction, ancient workers often used rammed earth, which included a mix of organic materials like soil and gravel that are compacted together, to build the massive wall.
While these materials may be more susceptible to erosion than other materials, such as solid stones, they often help promote the growth of biocrusts. This living stucco is made up of microorganisms that are capable of photosynthesis called cyanobacteria, mosses and lichens that help reinforce the construction, especially in arid and semi-arid parts of the country. “Ancient builders knew which materials could make the structure more stable,” said Bo Xiao, a professor of soil science at China Agricultural University in Beijing. “To enhance the mechanical strength, the rammed earth of the wall was always constructed with clay, sand and other adhesives like lime by the original builders,” he said. These ingredients provide fertile ground for the organisms that build biocrusts. To test the strength and integrity of the Great Wall, researchers collected samples at eight different sections built between 1368 and 1644 BC during the Ming Dynasty. They found that 67 per cent of the samples contained ‘biocrusts’, which Xiao called “ecosystem engineers.” Using portable mechanical instruments, both on site and back at the laboratory, they measured the samples’ mechanical strength and soil stability and compared that data to wall segments containing only bare rammed earth. They found that the biocrust samples were sometimes three times stronger than the plain rammed earth samples. Samples containing moss were particularly hearty. This is because the cyanobacteria and other life forms within the biocrust secreted substances, such as polymers, that would tightly “bind together” with the rammed earth particles, helping “strengthen their structural stability” by creating what was essentially cement, Xiao said. “These cementitious substances, biological filaments and soil aggregates within the biocrust layer finally form a cohesive network with strong mechanical strength and stability against external erosion.”