Courtesy of Neomatica:
Physicists from the Hong Kong University of Science and Technology have created a thin metasurface material which functions as a near perfect sound absorber tunable to a desired frequency. Under some conditions more than one frequency is perfectly absorbed. Unlike conventional sound absorbing material that is sometimes only effective when meters thick, the metasurface is deeply “subwavelength” and therefore much thinner.
Current sound absorption materials must be of a thickness comparable to the wavelength of the sounds, which for human hearing ranges from 17 meters to 17 millimeters for low to high frequencies respectively. Low frequency sounds are therefore difficult to damp without many meters of absorbent material.
The new metamaterial relies upon a “decorated membrane resonator” (DMR) which resembles a tiny drum membrane embedded in and coupled to a solid support, in the center of which is a platelet. The dimensions explored by the research team was a membrane 9 cm across, with thickness less than 0.2 mm, holding a platelet in the center 2 cm in diameter. Crucially, the membrane’s elastic modulus must be very low for the harmonics of the metasurface to correspond to the wavelengths of airborne sounds. A reflecting backing then sandwiches a sealed gas layer.
The metasurface exhibits resonance at audible wavelengths such that there is near total absorption of sound, and dissipation of the energy along the lossy membrane.
The entire system exhibits “impedance matching” to sound waves in air. The two consequences of which are that the surface is an excellent absorber of energy and does not reflect waves when absorbing sound of a particular wavelength. Both the sandwiched gas as well as the reflective backing surface are essential for giving rise to the high impedance. The authors show that the resonant frequency (the frequency of sound that is best absorbed) is adjustable by varying the thickness of the gas layer.
Most interestingly the researchers proceed to show that the vibrations induced in the platelet-membrane system can be coupled to energy generation, with a sound-to-electrical conversion efficiency of 23%.
The catch of course is that because each DMR type of the metasurface absorbs a limited frequency range of sounds, more than one layer would be needed to catch multiple frequencies or a single layer must contain a number of differently-sized DMRs. For some applications when the wavelength of the sound needed to be absorbed is well-known and narrow, a single DMR metasurface would be sufficient.
Dr. Guancong Ma led the research. Professor Ping Sheng was the senior author of the study.
The research was published on Jun 1, 2014 in Nature Materials.