Materials made from tapered chains of spherical beads could help dampen high-pitched sounds, theoretical physicists report.
The impacts of high-pitched sounds—those that lie at the upper range of human hearing or just beyond—on health are uncertain. But some research suggests that effects could include nausea, headaches, dizziness, impaired hearing, or other symptoms.
“There is a fair amount of ultrasonic stuff around us, and much of it has effects that are unknown. In warmer areas, you have pest control systems that are strongly reliant on ultrasonic emissions to drive out the pests. You have ultrasonics from machinery, from drilling. Certain lamps may emit these high-frequency noises,” says Surajit Sen, professor of physics at the University at Buffalo. “What does it do to our hearing? And in return, what does it do to our brain?
“Because of these unknowns, we thought it would be of potential value to design a system that kills off high-frequency sound.”
The new research appears in the journal Granular Matter.
The study used computational modeling to explore how well various materials would dampen incoming sounds with frequencies up to 20 kilohertz—high enough that only some people can hear these noises.
Sen and coauthor Luís Paulo Silveira Machado, professor of physics at the Federal University of Pará in Brazil, looked into a number of materials, all made from spherical beads of varying sizes surrounded by plastic walls.
The best set-up they found consisted of tapered chains of beads made from a metal called tungsten carbide, alternating with tapered chains of beads made from a plastic called Delrin. In computer simulations, this system effectively helped to filter high-frequency noises of varying loudness, greatly reducing these sounds.
The scientists have not yet tested the material in the laboratory. But if it works, the noise-filtering system could be used in headphones or other barriers that dampen high-frequency sound, the researchers say.
“An advantage of the proposed device is its simple configuration: spherical beads properly confined and positioned,” Machado says. “This proposal allows a prototype of easy construction, with low cost and little maintenance. In addition, its configuration is scalable, being adaptable for small or large volumes. Our next step is to redirect the output signals, which is under study.”
Machado did part of the work as a visiting scholar at the University at Buffalo with the financial support of his home university, and Sen’s research has partial support from a Fulbright-Nehru Academic and Professional Excellence Fellowship.
Source: University at Buffalo