The human body is an amazingly complex bit of kit. Replicating it with bionic technology presents challenges on many fronts, including the formidable task of mimicking our sense of touch. This goal could now be a little closer thanks to a breakthrough in carbon nanotube processing by scientists at Oak Ridge National Laboratory. Borrowing from conventional methods of making glass fiber, the researchers managed to cram 19,600 individual carbon nanotube-containing channels into fibers just four times thicker than a human hair, putting the artificial structure on a scale similar to the tiny neural bundles that make up our nerve pathways.
"Our goal is to use our discovery to mimic nature's design using artificial sensors to effectively restore a person's ability to sense objects and temperatures," said Ilia Ivanov, a researcher in the Center for Nanophase Materials Sciences Division.
"The human hand has a density of receptors at the fingertips of about 2,500 per square centimeter and about 17,000 tactile receptors in the hand," Ivanov said. "So in terms of density of channels, we are already in the range needed for 17,000 receptors in the hand."
Carbon nanotubes are not only incredibly small, they also conduct electricity, which makes them ideal for mimicking the nervous system. In the ORNL composite structure, each carbon nanotube is electrically insulated by glass so each one can carry individual signals.
The researchers say the next step is demonstrating this individual communication and achieving high-conductivity.
Ivanov and colleagues at ORNL recently published a paper in Nanotechnology.
Want a cleaner, faster loading and ad free reading experience?
Try New Atlas Plus. Learn more