Extraordinary acoustic absorption induced by hybrid resonance and electrical energy generation from sound by hybrid resonant metasurface

What is claimed is: 1. A sound absorbing metamaterial comprising an acoustic impedance-matched surface configured to minimize reflection from an incident acoustic wave, the surface comprising: an elastic or flexible membrane; a relatively solid surface provided as a reflective surface and positioned behind the membrane and separated by a predetermined distance from the elastic or flexible membrane and forming a fluid space between the membrane and the solid surface; and a substantially rigid mass mounted on the membrane, whereby the elastic membrane with the mass establish a plurality of eigenfrequencies for resonance. 2. The sound absorbing metamaterial of claim 1 , wherein: the eigenfrequencies are selected so that the metamaterial causes an incident acoustic wave to generate minimal reflection of acoustic energy. 3. The sound absorbing metamaterial of claim 1 , wherein: the membrane and the reflective surface form part of a sealed enclosure sufficiently sealed to establish a sealed or restricted enclosure comprising the fluid space, the sealing or restriction restricting escape or intake of fluid resulting from acoustic vibrations. 4. The sound absorbing metamaterial of claim 3 , wherein the structure provides an anomalous effective mass density behavior of membrane-type acoustic metamaterials (MAMs) near an anti-resonance state, which, in combination with the reflective surface and the fluid space between the membrane and the solid surface, can match the impedance of air at predetermined frequencies, thereby substantially attenuating reflected sound and allowing substantial absorption of incident acoustic waves. 5. The sound absorbing metamaterial of claim 3 , further comprising: the substantially rigid mass having a lateral dimension smaller than a lateral dimension of the sealed or restricted enclosure. 6. The sound absorbing metamaterial of claim 3 , wherein the fluid space between the membrane and the solid surface has a height established by the predetermined distance from the elastic or flexible membrane at a mean or resting position of the membrane, and a radius of the sealed enclosure are much smaller than the wavelengths of sound in air at the eigenfrequencies. 7. The sound absorbing metamaterial of claim 1 , wherein the predetermined distance of separation of the flexible membrane from the relatively solid surface corresponds to a maximum peak amplitude or a semi amplitude of the incident acoustic wave minus energy absorbed at the elastic membrane. 8. The sound absorbing metamaterial of claim 1 , further comprising the membrane having a predetermined amount of in-planar pre-stress applied thereto. 9. The sound absorbing metamaterial of claim 1 , further comprising: the relatively solid surface provided as a reflective surface comprising a hard material having acoustic reflecting characteristics. 10. The sound absorbing metamaterial of claim 1 , further comprising: the relatively solid surface provided as a reflective surface comprising a soft material having acoustic absorption characteristics. 11. The sound absorbing metamaterial of claim 1 , further comprising: an electrical generator operatively connected to the membrane, and capable of extracting vibrational energy from the membrane sufficiently to attenuate the vibrational energy, the extracting of the vibrational energy converting part of the absorbed sound energy into electrical energy. 12. The sound absorbing metamaterial of claim 11 , further comprising: a permanent magnet affixed to at least one of the membrane or a region adjacent the membrane; an electrical conductor fixed to the sound absorbing metamaterial in such a way that movement of the membrane results in relative movement between the permanent magnet and the electrical conductor; and electrical connections with the electrical conductor capable of extracting electrical energy from the electrical conductor. 13. The sound absorbing metamaterial of claim 11 , further comprising: a thin sheet supported above the membrane and separated from the membrane sufficiently to respond to wind movement, whereby the wind movement causes the thin sheet to flap and undulate, resulting in pressure changes at the membrane, thereby generating electrical energy in response to the wind movement. 14. The sound absorbing metamaterial of claim 1 , further comprising: an electrical generator operatively connected to the membrane, and capable of extracting vibrational energy from the membrane sufficiently to attenuate the vibrational energy, the extracting of the vibrational energy providing an increase in a maximum energy absorption of the sound absorbing metamaterial beyond that afforded by the sound absorbing metamaterial without the electrical generator. 15. A sound absorbing metamaterial comprising an acoustic impedance-matched surface configured to minimize reflection from an incident acoustic wave, the surface comprising: an elastic or flexible membrane; a relatively solid surface provided as a reflective surface and positioned behind the membrane and separated by a predetermined distance from the elastic or flexible membrane and forming a fluid space between the membrane and the solid surface; a substantially rigid mass mounted on the membrane, whereby the elastic membrane with the mass establish a plurality of eigenfrequencies; and an electric generator responsive to movement of the membrane. 16. The sound absorbing metamaterial of claim 15 , wherein: the eigenfrequencies are selected so that the metamaterial causes an incident acoustic wave to generate minimal reflection of acoustic energy. 17. The sound absorbing metamaterial of claim 15 , wherein: the membrane and the reflective surface form part of a sealed enclosure sufficiently sealed to establish a sealed or restricted enclosure comprising the fluid space, the sealing or restriction restricting escape or intake of fluid resulting from acoustic vibrations. 18. The sound absorbing metamaterial of claim 17 , wherein the structure provides an anomalous effective mass density behavior of membrane-type acoustic metamaterials (MAMs) near an anti-resonance state, which, in combination with the reflective surface and the fluid space between the membrane and the solid surface, can match the impedance of air at predetermined frequencies, thereby substantially attenuating reflected sound and allowing substantial absorption of incident acoustic waves. 19. The sound absorbing metamaterial of claim 17 , further comprising: the substantially rigid mass having a lateral dimension smaller than a lateral dimension of the sealed or restricted enclosure. 20. The sound absorbing metamaterial of claim 17 , wherein the fluid space between the membrane and the solid surface has a height established by the predetermined distance from the elastic or flexible membrane at a mean or resting position of the membrane, and a radius of the sealed enclosure are much smaller than the wavelengths of sound in air at the eigenfrequencies. 21. The sound absorbing metamaterial of claim 15 , wherein the predetermined distance of separation of the flexible membrane from the relatively solid surface corresponds to a maximum peak amplitude or a semi amplitude of the incident acoustic wave minus energy absorbed at the elastic membrane. 22. The sound absorbing metamaterial of claim 15 , further comprising the membrane having a predetermined amount of in-planar pre-stress applied thereto. 23. The sou