Low frequency sound attenuation is a challenging task, because of the severe mass, stiffness and volume constraints on the absorbing and/or reflecting barriers. Recently, significant improvements in low frequency sound attenuation has been achieved by introducing the acoustic metafoam concept, which combines the mechanism of conventional acoustic foams - high viscothermal dissipation - with the working principle of locally resonant acoustic metamaterials - wave attenuation at low frequencies. However, the attenuation improvement provided by periodic materials containing identical resonators is confined to a narrow frequency range. To overcome this limitation, graded acoustic metafoams are proposed and studied here, where a distribution of l...
Sound attenuation with conventional acoustic materials is subject to the mass law and requires massi...
International audienceThis presentation examines a perforated resonant material, in which the princi...
Depending on the frequency, waves can either propagate (transmission band) or be attenuated (attenua...
Low frequency sound attenuation is a challenging task, because of the severe mass, stiffness and vol...
Acoustic metafoams are novel materials recently proposed for low frequency sound attenuation. The de...
Acoustic foams are commonly used for sound attenuation purposes. Due to their porous microstructure,...
\u3cp\u3eAcoustic foams are commonly used for sound attenuation purposes. Due to their porous micros...
We report the development of ¯lm type acoustic metamaterials by utilizing micro scale reson...
The study of metamaterials represents a new research field in the applied acoustics. This paper desc...
The so-called Locally Resonant Acoustic Metamaterials (LRAM) are considered for the design of specif...
Over the past decades, tightening ecologic and economic requirements have urged industry to introduc...
International audienceAn acoustic metamaterial absorber comprised of periodically distributed caviti...
Sound attenuation with conventional acoustic materials is subject to the mass law and requires mass...
Sound attenuation with conventional acoustic materials is subject to the mass law and requires massi...
International audienceThis presentation examines a perforated resonant material, in which the princi...
Depending on the frequency, waves can either propagate (transmission band) or be attenuated (attenua...
Low frequency sound attenuation is a challenging task, because of the severe mass, stiffness and vol...
Acoustic metafoams are novel materials recently proposed for low frequency sound attenuation. The de...
Acoustic foams are commonly used for sound attenuation purposes. Due to their porous microstructure,...
\u3cp\u3eAcoustic foams are commonly used for sound attenuation purposes. Due to their porous micros...
We report the development of ¯lm type acoustic metamaterials by utilizing micro scale reson...
The study of metamaterials represents a new research field in the applied acoustics. This paper desc...
The so-called Locally Resonant Acoustic Metamaterials (LRAM) are considered for the design of specif...
Over the past decades, tightening ecologic and economic requirements have urged industry to introduc...
International audienceAn acoustic metamaterial absorber comprised of periodically distributed caviti...
Sound attenuation with conventional acoustic materials is subject to the mass law and requires mass...
Sound attenuation with conventional acoustic materials is subject to the mass law and requires massi...
International audienceThis presentation examines a perforated resonant material, in which the princi...
Depending on the frequency, waves can either propagate (transmission band) or be attenuated (attenua...