Scientists have re-created one of nature’s most sensitive sound detectors, the tiny hairs found on body parts of crickets, which allow them to hear predators and make an escape before they get close enough to catch them.
Published today in the Journal of Micromechanics and Microengineering, an
Crickets spend most of their lives on the ground, making them vulnerable to predators. Species such as the wood cricket Nemobius sylvestris have developed a pair of hairy appendages at the abdominal end of their body called cerci, which detect fluctuations in air currents, the kind that might be caused by the beating of a wasp’s wings or the jump of an attacking spider.
Each of the hairs on a cricket’s cerci is lodged in a socket, which allows them to move in a preferred direction. Airflow causes a drag force on the hair, rotating its base and firing specific neural cells, which allows the cricket to pinpoint low-frequency sound from any given direction by using the combined neural information from all the sensory hairs on the cerci.
Physicists at the
The Twente team, led by Gijs Krijnen and Remco Wiegerink, have shown that they can make mechanical hair sensors and are able to fabricate them in large arrays of long hairs for the first time. They have also obtained experimental results, which reveal how good these artificial cricket hairs are at sensing low-frequency sound.
The work was carried out by the MESA+ research institute at the University of Twente, as part of the European Union project CICADA (Cricket Inspired perception and Autonomous Decision Automata), which aims to develop a life-like perception system by studying biological concepts and trying to mimic these using the latest fabrication technologies.
Cricket hairs are energy efficient sensors, and crickets are thought to perceive flows with energies as small as or even below thermal noise levels (the background “noise” caused by the Brownian motion of particles). By evolution, the cricket has fine-tuned the hairs in order to gain as much energy from the airflow as possible.
The cricket hair canopy also shows outstanding directivity, since acoustic flow, in contrast to acoustic pressure, not only has a magnitude but also a direction. Sensitivity and directivity help crickets to perceive and escape from attacking predators, such as the wolf spider. Because of their optimised performance, cricket acoustic sensory hairs are very interesting structures to bio-mimic in man-made acoustic sensors.
The Twente team built a mechanical array with up to a few hundred artificial hairs using MEMS technology. The sensors are made by depositing and structuring various thin layers of electrically insulating and conducting materials, creating structured electrodes on a suspended membrane. The structured electrodes form two capacitors with the underlying substrate.
Long hairs, made of a photo-structurable polymer (SU-8), are put on top of the membranes. Airflow causes drag-forces on the hairs and so the membranes rotate, leading to a change in capacitance value of the capacitors.
Marcel Dijkstra, a member of the Twente team, said: “These sensors are the first step towards a variety of exciting applications as well as further scientific exploration. Their small size and low energy consumption make them excellent for application in large sensor networks, whereas their mechanical nature allows for mechanical filtering and parametric amplification. We could use them to visualise airflow on surfaces, such as an aircraft fuselage.”
In a more advanced stage, the structures may form a stepping-stone towards the fabrication of hairs operating in fluids, such as found in the inner ears of mammals. The team is now producing newer generations of hairs, which they expect to deliver sensitivities at least one order of magnitude better than what has been presented in the paper.