Silk symphony in spiders' web
Scientists have translated the structure of a spider’s web into music.
Spiders are master builders, expertly weaving strands of silk into intricate 3D webs that serve as the spider’s home and hunting ground.
If humans could enter the spider’s world, they could learn about web construction, arachnid behavior and more.
“The spider lives in an environment of vibrating strings,” says Dr Markus Buehler, the project’s principal investigator, who presented the work at this week’s meeting of the American Chemical Society.
“They don’t see very well, so they sense their world through vibrations, which have different frequencies.”
Such vibrations occur, for example, when the spider stretches a silk strand during construction, or when the wind or a trapped fly moves the web.
Dr Buehler, who is also a musician, wondered if he could extract rhythms and melodies of non-human origin from natural materials, such as spider webs.
“Webs could be a new source for musical inspiration that is very different from the usual human experience,” he says.
In addition, by experiencing a web through hearing as well as vision, Dr Buehler and colleagues at the Massachusetts Institute of Technology (MIT), hoped to gain new insights into the 3D architecture and construction of webs.
With these goals in mind, the researchers scanned a natural spider web with a laser to capture 2D cross-sections and then used computer algorithms to reconstruct the web’s 3D network.
The team assigned different frequencies of sound to strands of the web, creating “notes” that they combined in patterns based on the web’s 3D structure to generate melodies.
The researchers then created a harp-like instrument and played the spider web music in several live performances around the world.
The team also made a virtual reality setup that allowed people to visually and audibly “enter” the web.
“The virtual reality environment is really intriguing because your ears are going to pick up structural features that you might see but not immediately recognize,” Dr Buehler says.
“By hearing it and seeing it at the same time, you can really start to understand the environment the spider lives in.”
To gain insights into how spiders build webs, the researchers scanned a web during the construction process, transforming each stage into music with different sounds.
“The sounds our harp-like instrument makes change during the process, reflecting the way the spider builds the web,” Dr Buehler says.
“So, we can explore the temporal sequence of how the web is being constructed in audible form.”
This step-by-step knowledge of how a spider builds a web could help in devising ‘spider-mimicking’ 3D printers that build complex microelectronics.
“The spider’s way of ‘printing’ the web is remarkable because no support material is used, as is often needed in current 3D printing methods,” he says.
In other experiments, the researchers explored how the sound of a web changes as it’s exposed to different mechanical forces, such as stretching.
“In the virtual reality environment, we can begin to pull the web apart, and when we do that, the tension of the strings and the sound they produce change. At some point, the strands break, and they make a snapping sound,” Dr Buehler says.
The team is also interested in learning how to communicate with spiders in their own language.
They recorded web vibrations produced when spiders performed different activities, such as building a web, communicating with other spiders or sending courtship signals.
Although the frequencies sounded similar to the human ear, a machine learning algorithm correctly classified the sounds into the different activities.
“Now we’re trying to generate synthetic signals to basically speak the language of the spider,” Dr Buehler says.
“If we expose them to certain patterns of rhythms or vibrations, can we affect what they do, and can we begin to communicate with them? Those are really exciting ideas.”