Carbon nanotube transducers on propeller blades for sound control

What is claimed is: 1. An aerial vehicle comprising: a first motor configured to rotate a propeller such that the propeller generates a lifting force; the propeller including: a hub that is coupled to the first motor so that the first motor can rotate the propeller; and a propeller blade extending from the hub, the propeller blade including an upper surface and a lower surface; a propeller duct positioned around the propeller; a plurality of carbon nanotube transducers formed as a mesh material and positioned over an exit of the propeller duct; and a sound controller in communication with the plurality of carbon nanotube transducers to provide a signal to the plurality of carbon nanotube transducers to cause the plurality of carbon nanotube transducers to activate, wherein the signal causes the plurality of carbon nanotube transducers to generate an anti-sound that interferes with a sound generated by a rotation of the propeller blade. 2. The aerial vehicle of claim 1 , further comprising: a sensor in communication with the sound controller to measure the sound generated by the rotation of the propeller blade; and wherein the anti-sound is determined by the sound controller based at least in part on the measured sound. 3. The aerial vehicle of claim 1 , further comprising: a motor controller in communication with the first motor, the motor controller causing the first motor to rotate the propeller blade at a defined revolutions per minute (“RPM”); and wherein the anti-sound is determined based at least in part on a sound anticipated to be generated by the rotation of the propeller blade at the defined RPM. 4. The aerial vehicle of claim 1 , further comprising: an electromagnetic coil wound around the first motor and coupled to the sound controller; and a plurality of magnets arranged adjacent to the electromagnetic coil and in an alternating polarity such that an electrical current is generated by the electromagnetic coil in response to a rotation of the first motor and the electromagnetic coil moving with respect to the plurality of magnets. 5. The aerial vehicle of claim 4 , wherein the sound controller utilizes the electrical current. 6. An aerial vehicle, comprising: a motor; a propeller coupled to and rotated by the motor, the propeller including a surface area having an upper side, a lower side, a leading edge, and a trailing edge; a propeller duct positioned around the propeller; a carbon nanotube transducer formed in a mesh material and positioned over at least a portion of at least one of an entrance or an exit of the propeller duct; and a sound controller in communication with the carbon nanotube transducer to provide a signal to the carbon nanotube transducer to cause the carbon nanotube transducer to activate, wherein the signal causes the carbon nanotube transducer to generate an anti-sound that interferes with a sound generated by a rotation of the propeller. 7. The aerial vehicle of claim 6 , further comprising: a piezoelectric thin-film transducer in communication with the sound controller, the piezoelectric thin-film transducer receiving the signal and generating the anti-sound. 8. The aerial vehicle of claim 6 , wherein: a second carbon nanotube transducer is positioned on the upper side of the propeller; and a piezoelectric thin-film transducer is positioned on the lower side of the propeller. 9. The aerial vehicle of claim 8 , wherein the sound controller is in communication with the piezoelectric thin-film transducer to provide the signal to the piezoelectric thin-film transducer to cause the piezoelectric thin-film transducer to activate. 10. The aerial vehicle of claim 6 , further comprising: a sensor configured to measure a sound generated by the aerial vehicle; and wherein at least one of a frequency or an amplitude of the anti-sound is determined based at least in part on the measured sound. 11. The aerial vehicle of claim 10 , wherein the sensor is coupled to a hub of the propeller. 12. The aerial vehicle of claim 10 , the sound controller including: a communication component configured to receive a wireless communication that indicates the anti-sound to be generated by the carbon nanotube transducer, wherein the anti-sound is determined based at least in part on a revolutions per minute (RPM) of the propeller or a position of the aerial vehicle. 13. The aerial vehicle of claim 6 , wherein the sound controller includes: an anti-sound table indicating anti-sounds to be generated by the carbon nanotube transducer, wherein anti-sounds of the anti-sound table correspond to a revolutions per minute (RPM) of the propeller. 14. The aerial vehicle of claim 6 , wherein at least a portion of the propeller duct includes a transducer configured to generate the anti-sound. 15. A method for altering a sound generated by a rotation of a propeller blade, the method comprising: determining a revolutions per minute (RPM) of the propeller blade; obtaining from a memory, an indication of a sound anticipated to be generated by the propeller blade when rotating at the RPM; determining an anti-sound that will cause interference with the sound; and sending a signal to a carbon nanotube transducer included in a mesh material that is positioned over at least a portion of at least one of an entrance or an exit of a propeller duct around the propeller blade to cause the carbon nanotube transducer to generate the anti-sound such that the anti-sound causes interference with the sound. 16. The method of claim 15 , further comprising; determining additional sound generated by an aerial vehicle as the aerial vehicle is operating and rotating the propeller blade; and wherein the anti-sound is determined to cause interference with the sound and the additional sound. 17. The method of claim 15 , further comprising: measuring with a sensor coupled to an aerial vehicle a net-effect resulting from a combination of the sound and the anti-sound; and altering the anti-sound based at least in part on the net-effect. 18. The method of claim 15 , wherein the anti-sound is determined based at least in part on a machine learning system that considers at least one of the RPM of the propeller blade, a position of an aerial vehicle, an operational condition, or an environmental condition. 19. The method of claim 15 , wherein sending includes sending the signal to a plurality of carbon nanotube transducers included in the mesh material that is positioned over at least a portion of at least one of the entrance or the exit of the propeller duct around the propeller blade to cause each of the plurality of carbon nanotube transducers to generate the anti-sound such that the anti-sound causes interference with the sound. 20. The method of claim 17 , wherein the anti-sound is determined based at least in part on an environment in which the aerial vehicle is operating.