Supercoupling power dividers, and methods for making and using same

What is claimed: 1. A supercoupling power divider, comprising an acoustic input port having an input cross-sectional area, where the acoustic input port is adapted for receiving an acoustic signal having an impedance; two or more acoustic output ports, each acoustic output port having an output cross-sectional area, where the combined output cross-sectional areas of the two or more output ports is equal to the input cross-sectional area, and where the two or more acoustic output ports are adapted for transmitting the acoustic signal; and an acoustic path extending from the acoustic input port to the two or more acoustic output ports, the acoustic path having a variable length and a path cross-sectional area that is greater than the first cross-sectional area wherein acoustic impedance at the acoustic input port is equal to the combined acoustic impedances at the two or more acoustic output ports. 2. The supercoupling power divider of claim 1 , wherein the acoustic path exhibits compressibility-near-zero (CNZ) acoustic supercoupling. 3. The supercoupling power divider of claim 1 , wherein the acoustic input port receives the acoustic signal from an input waveguide. 4. The supercoupling power divider of claim 3 , where the acoustic signal is provided by an acoustic signal source in communication with the input waveguide. 5. The supercoupling power divider of claim 4 , where the acoustic signal source is selected from the group consisting of drivers, speakers, and horns. 6. The supercoupling power divider of claim 1 , wherein the two or more acoustic output ports transmit the acoustic signal through output waveguides. 7. The supercoupling power divider of claim 1 , where the acoustic path comprises an air-filled channel and a boundary layer comprising a material having a Young's modulus (E) that is about 200 GPa or greater. 8. The supercoupling power divider of claim 7 , wherein the boundary layer minimizes losses due to viscothermal boundary effects. 9. The supercoupling power divider of claim 1 , wherein the acoustic path has a path cross-sectional area that is at least 16 times greater than the input cross-sectional area. 10. The supercoupling power divider of claim 1 , wherein the acoustic path comprises a first resonant mode and a second resonant mode, wherein the second resonant mode does not interfere with the first resonant mode. 11. The supercoupling power divider of claim 1 , wherein the output cross-sectional areas of each of the two or more output ports is the same, and the acoustic impedance at the two or more output ports is the same. 12. The supercoupling power divider of claim 1 , wherein the output cross-sectional areas of each of the two or more output ports is different, and the acoustic impedance at each of the two or more output ports is proportional to its output cross-sectional area. 13. A method for achieving supercoupling in an acoustic path, comprising: providing an acoustic path comprising an air-filled channel and a boundary layer comprising a material having a Young's modulus (E) that is about 200 GPa or greater, where the acoustic path has an acoustic input port and at least two acoustic output ports; providing a signal having an impedance at the acoustic input port, where the signal is transmitted through the acoustic path to the at least two acoustic output ports, wherein the total signal at the at least two acoustic output ports has an impedance equal to the impedance of the signal at the acoustic input port. 14. The method of claim 13 , wherein the acoustic path exhibits compressibility-near-zero (CNZ) acoustic supercoupling. 15. The method of claim 13 , wherein the acoustic input port receives the signal from an input waveguide. 16. The method of claim 15 , where the signal is provided by an acoustic signal source in communication with the input waveguide. 17. The method of claim 13 , where the acoustic path comprises an air-filled channel and a boundary layer comprising a material having a Young's modulus (E) that is about 200 GPa or greater. 18. The method of claim 13 , wherein the acoustic path comprises a first resonant mode and a second resonant mode, wherein the second resonant mode does not interfere with the first resonant mode. 19. The method of claim 13 , wherein the output cross-sectional areas of each of the two or more output ports is the same, and the acoustic impedance at the two or more output ports is the same. 20. The method of claim 13 , wherein the output cross-sectional areas of each of the two or more output ports is different, and the acoustic impedance at each of the two or more output ports is proportional to its cross-sectional area.