Actively tunable polar-dielectric optical devices

What is claimed is: 1. An actively tunable polar-dielectric optical device, comprising: a plurality of polar-dielectric SPhP nanoantennas fabricated from a plurality of polar-dielectric materials, a first portion of each nanoantenna being fabricated from a first polar-dielectric material and a second portion of each nanoantenna being fabricated from a second polar-dielectric material, each of the first and second polar-dielectric materials being configured to exhibit surface phonon polaritons (SPhPs) when it is exposed to a corresponding incident infrared optical beam having at least one wavelength within a Reststrahlen band of that polar-dielectric material, a presence of SPhPs in each of the polar-dielectric materials affecting at least one optical property of the device, a value of the at least one optical property of the structure being dependent on a concentration of charge carriers in the polar-dielectric materials; and a controllable source of charge carriers configured to inject additional charge carriers into at least one of the polar-dielectric materials; wherein the at least one optical property is a resonant wavelength λ res in the first polar-dielectric material; wherein a first injection of charge carriers into the first polar-dielectric material is configured to produce a desired permittivity ∈ 1 in the first polar-dielectric material; and wherein a second injection of charge carriers into the second polar-dielectric material is configured to produce a desired index of refraction n 2 in the second polar-dielectric material; and wherein the first and second injections of charge carriers are further configured to produce a desired resonant wavelength λ res (∈ 1 , n 2 ) in the first polar-dielectric material. 2. The actively tunable polar-dielectric optical device according to claim 1 ; wherein the plurality of polar-dielectric SPhP nanoantennas are fabricated from a plurality of polar-dielectric materials in a stacked structure. 3. The actively tunable polar-dielectric optical device according to claim 1 ; wherein the plurality of polar-dielectric SPhP nanoantennas are fabricated from a plurality of polar-dielectric materials configured as a plurality of discrete conformally overgrown layers. 4. The actively tunable polar-dielectric optical device according to claim 1 ; wherein the plurality of polar-dielectric SPhP nanoantennas are fabricated from a plurality of polar-dielectric materials wherein the second polar-dielectric material is embedded within a structure formed from the first polar-dielectric material. 5. The actively tunable polar-dielectric optical device according to claim 1 ; wherein the charge carrier source is a controllable optical pump beam incident on the structure; and wherein the injection of charge carriers into the at least one the polar-dielectric materials is controlled by controlling an intensity of the pump beam incident on that polar-dielectric material. 6. The actively tunable polar-dielectric optical device according to claim 1 ; wherein at least one of the polar-dielectric materials is situated adjacent to one of a doped substrate, a metallic film, and a van der Waals film, and wherein the charge carrier source is a controllable electrical source operatively connected to the at least one polar-dielectric material and to the one of the substrate, the metallic film, and the van der Waals film, the controllable electrical source being configured to controllably inject charge carriers from the substrate, the metallic film, or the van der Waals film into at the at least one polar-dielectric material; wherein the injection of charge carriers into the at least one polar-dielectric materials is controlled by controlling an electrical signal from the electrical source. 7. The actively tunable polar-dielectric optical device according to claim 1 ; wherein at least one of the polar-dielectric materials is situated between a first substrate and a contact layer comprising one of a second substrate, a metallic film or a van der Waals film and wherein the charge carrier source is a controllable electrical source operatively connected to the substrate and the contact layer, the controllable electrical source being configured to controllably inject charge carriers of one polarity (electron or hole) from the substrate and of the opposite polarity from the contact layer into at the at least one polar-dielectric material; wherein the injection of charge carriers into the at least one polar-dielectric materials is controlled by controlling an electrical signal from the electrical source. 8. The actively tunable polar-dielectric optical device according to claim 1 , wherein at least one of the polar-dielectric materials comprises SiC, GaN, BN, BC, AN, Al 2 O 3 , SiO 2 , or AlGaN. 9. The actively tunable polar-dielectric optical device according to claim 1 , wherein at least one of a corresponding extraordinary and a corresponding ordinary permittivity of at least one of the polar-dielectric materials is actively tuned by controlling the number of charge carriers injected into the device. 10. The actively tunable polar-dielectric optical device according to claim 1 , wherein a birefringence of at least one of the polar-dielectric materials is actively tuned by controlling the number of charge carriers injected into the device. 11. An actively tunable polar-dielectric optical device, comprising: a plurality of polar-dielectric SPhP nanoantennas fabricated from a plurality of polar-dielectric materials, a first portion of each nanoantenna being fabricated from a first polar-dielectric material and a second portion of each nanoantenna being fabricated from a second polar-dielectric material, each of the first and second polar-dielectric materials being configured to exhibit surface phonon polaritons (SPhPs) when it is exposed to a corresponding incident infrared optical beam having at least one wavelength within a Reststrahlen band of that polar-dielectric material, a presence of SPhPs in each of the polar-dielectric materials affecting at least one optical property of the device, a value of the at least one optical property of the structure being dependent on a concentration of charge carriers in the polar-dielectric materials; and a controllable source of charge carriers configured to inject additional charge carriers into at least one of the polar-dielectric materials; wherein a first injection of charge carriers into the first polar-dielectric material is configured to produce a desired permittivity ∈ 1 and a desired index of refraction n 1 in the first polar-dielectric material; and wherein a second injection of charge carriers into the second polar-dielectric material is configured to produce a desired permittivity ∈ 2 and desired index of refraction n 2 in the second polar-dielectric material; and wherein the first and second injections of charge carriers are further configured to produce a desired first resonant wavelength λ res (∈ 1 , n 2 ) in the first polar-dielectric material and a desired second resonant wavelength λ rTes (∈ 1 , n 1 ) in the second polar-dielectric material. 12. The actively tunable polar-dielectric optical device according to claim 11 ; wherein the plurality of polar-dielectric SPhP nanoantennas are fabricated from a plurality of polar-dielectric materials in a stacked structure. 13. The actively tunable polar-dielectric optical device according to claim 11 ; wherein the plurality of polar-dielectric SPhP nanoantennas are fabricated from a plurality of polar-dielectric materials configured as a plurality of discrete conformally overgrown layers. 14. The acti