Systems and methods for implementing electrically tunable metasurfaces

What claimed is: 1. An electrically tunable metasurface reflectarray comprising: a mirrored surface; a conductive layer; a dielectric layer; wherein the conductive layer and the dielectric layer are in direct contact, and thereby define a conductor-dielectric interface; a plurality of subwavelength antenna elements; and an electrical power source configured to establish a potential difference between at least one subwavelength antenna element and the mirrored surface; wherein a potential difference between a subwavelength antenna element and the mirrored surface applies an electric field to a corresponding region of the electrically tunable metasurface reflectarray; wherein each of a plurality of subwavelength antenna elements is independently addressable by the potential difference between a subwavelength antenna element and the mirrored surface using a circuity; wherein any applied electric fields in conjunction with the geometry and the material composition of each of the subwavelength antenna elements, the conductive layer, and the dielectric layer, enable the electrically tunable metasurface reflectarray to measurably augment the propagation characteristics of incident electromagnetic waves. 2. The electrically tunable metasurface reflectarray of claim 1 , wherein any applied electric fields in conjunction with the geometry and the material composition of each of the subwavelength antenna elements, the conductive layer, and the dielectric layer, enable the electrically tunable metasurface reflectarray to measurably augment the propagation characteristics of incident electromagnetic waves falling within at least some portion of the electromagnetic spectrum characterized by wavelengths of less than 10 μm. 3. The electrically tunable metasurface reflectarray of claim 2 , wherein the at least some portion of the electromagnetic spectrum is characterized by electromagnetic waves having wavelengths less than or equal to wavelengths approximately corresponding with those of near infrared electromagnetic waves. 4. The electrically tunable metasurface reflectarray of claim 3 , wherein when a region of the electrically tunable metasurface is exposed to an electric field, reflected incident electromagnetic waves falling within the at least some portion of the electromagnetic spectrum exhibit a phase shift based on the magnitude of the applied electric field. 5. The electrically tunable metasurface reflectarray of claim 3 , wherein the at least some portion of the electromagnetic spectrum is characterized by electromagnetic waves having wavelengths approximately corresponding with those of near infrared electromagnetic waves. 6. The electrically tunable metasurface reflectarray of claim 3 , wherein the at least some portion of the electromagnetic spectrum is characterized by electromagnetic waves having wavelengths less than or equal to wavelengths approximately corresponding with those of visible light. 7. The electrically tunable metasurface reflectarray of claim 6 , wherein the at least some portion of the electromagnetic spectrum is characterized by electromagnetic waves having wavelengths approximately corresponding with those of visible light. 8. The electrically tunable metasurface reflectarray of claim 1 , wherein the circuitry is a control circuitry. 9. The electrically tunable metasurface reflectarray of claim 1 , wherein: the conductive layer comprises one of: a nitride based material; silver; copper; gold; aluminum; an alkali metal; an alloy; a transparent conducting alloy; a conducting nitride; titanium nitride; and graphene. 10. The electrically tunable metasurface reflectarray of claim 1 , wherein the conductive layer comprises indium tin oxide. 11. The electrically tunable metasurface reflectarray of claim 10 , wherein the dielectric layer comprises a dielectric oxide. 12. The electrically tunable metasurface reflectarray of claim 11 , wherein the dielectric layer comprises aluminum oxide. 13. The electrically tunable metasurface reflectarray of claim 12 , wherein: the mirrored surface comprises gold; and at least one of the plurality of subwavelength antenna elements comprises gold. 14. The electrically tunable metasurface reflectarray of claim 13 , wherein when a region of the electrically tunable metasurface reflectarray is exposed to an electric field, the charge carrier concentration at the conductor-dielectric interface within that region is altered based on the magnitude of the applied electric field, and this alteration causes a phase shift in reflected incident electromagnetic waves falling within the at least some portion of the electromagnetic spectrum. 15. The electrically tunable metasurface reflectarray of claim 14 , wherein a variation in charge carrier concentration from 1×10 19 cm −3 to 1×10 21 cm −3 is sufficient to shift the phase of reflected incident electromagnetic waves falling within the at least some portion of the electromagnetic spectrum by at least 2π. 16. The electrically tunable metasurface reflectarray of claim 1 , wherein at least one of the plurality of subwavelength antenna elements conforms to a rod-shaped geometry. 17. The electrically tunable metasurface reflectarray of claim 1 , wherein at least one of the plurality of subwavelength antenna elements conforms to a V-shaped geometry. 18. The electrically tunable metasurface reflectarray of claim 1 , wherein at least one of the plurality of subwavelength antenna elements conforms to a split ring geometry. 19. The electrically tunable metasurface reflectarray of claim 18 , wherein each of the plurality of subwavelength antenna elements conforms to a split ring geometry.