Omnidirectional polarization independent all-dielectric light trapping scheme

What is claimed is: 1. A synergistic lossless omnidirectional light trapping scheme for a heterojunction photovoltaic cell for solar energy capture within the solar spectrum that receives light across normal angles of incidence, oblique angles of incidence, or both, the synergistic lossless omnidirectional light trapping scheme for the heterojunction photovoltaic cell comprising: an inorganic bilayer configuration of densely packed hexagonal arrays of nanoparticles, each nanoparticle of the hexagonal arrays being in physical contact with at least one alternative nanoparticle of the hexagonal arrays, the bilayer configuration including: a top optically tuned layer in contact with a bottom optically tuned layer, the top optically tuned layer comprised of a plurality of nonmetallic all-dielectric silica nanospheres, each of the plurality of nonmetallic all-dielectric silica nanospheres having a first diameter associated therewith; and the bottom optically tuned layer disposed beneath the top optically tuned layer, the bottom optically tuned layer comprised of a plurality of nonmetallic all-dielectric titania nanospheres, each of the plurality of nonmetallic all-dielectric titania nanospheres having a second diameter associated therewith, the second diameter being smaller than the first diameter; wherein the top optically tuned layer is configured to capture and funnel an incident light into the bottom optically tuned layer with reduced refractory loss; wherein subsequent to the incident light being captured by the top optically tuned layer, the incident light is configured to strike an internal surface of at least one of the plurality of nonmetallic all-dielectric silica nanospheres at an angle of at least 43°, whereby the incident light becomes reflected light as the reflected light contacts and travels on inner edges of the internal surface of the at least one of the plurality of nonmetallic all-dielectric silica nanospheres, such that a total internal reflection exists between the top optically tuned layer and an exterior air environment for normal angles of incidence, oblique angles of incidence, or both; and wherein the bottom optically tuned layer is adapted to receive the reflected light from the at least one of the plurality of nonmetallic all-dielectric silica nanospheres and scatter the reflected light in a direction away from the top optically tuned layer and toward a substrate, whereby a back-scattering of the reflected light is minimized, thereby optimizing a photo-conversion efficiency. 2. The synergistic lossless omnidirectional light trapping scheme of claim 1 , wherein the second diameter is less than half the size of the first diameter. 3. The synergistic lossless omnidirectional light trapping scheme of claim 1 , wherein a ratio of the first diameter to the second diameter is approximately 6:1. 4. The synergistic lossless omnidirectional light trapping scheme of claim 1 , wherein the substrate has a height of approximately 20 μm. 5. A heterojunction photovoltaic cell comprising: a substrate including a planar silicon surface passivated by a layer of aluminum oxide, a layer of graphene film that is p-doped with gold trichloride coating the planar silicon surface, with the substrate disposed beneath and in contact with a bottom optically tuned layer: an omnidirectional light trapping scheme comprising: an inorganic bilayer configuration of densely packed hexagonal arrays of nanoparticles, each nanoparticle of the hexagonal arrays being in physical contact with at least one alternative nanoparticle of the hexagonal arrays, the bilayer configuration including: a top optically tuned layer in contact with the bottom optically tuned layer, the top optically tuned layer comprised of a plurality of nonmetallic all-dielectric silica nanospheres, each of the plurality of nonmetallic all-dielectric silica nanospheres having an associated diameter; and the bottom optically tuned layer disposed beneath the top optically tuned layer, the bottom optically tuned layer comprised of a plurality of nonmetallic all-dielectric titania nanospheres, each of the plurality of nonmetallic all-dielectric titania nanospheres having an associated diameter smaller than the associated diameter of each of the plurality of all-dielectric silica nanospheres, wherein the top optically tuned layer is configured to capture and funnel an incident light into the bottom optically tuned layer with reduced refractory loss; and wherein the bottom optically tuned layer is adapted to receive the incident light from the at least one of the plurality of nonmetallic all-dielectric silica nanospheres and scatter the incident light in a direction away from the top optically tuned layer and toward the substrate, whereby a back-scattering of the reflected light is minimized, thereby optimizing a photo-conversion efficiency. 6. The photovoltaic cell of claim 5 , wherein whispering gallery modes are formed within the top optically tuned layer to direct light into the bottom optically tuned layer with reduced refractory loss. 7. The heterojunction photovoltaic cell of claim 5 , wherein the second diameter is less than half the size of the first diameter. 8. The heterojunction photovoltaic cell of claim 5 , wherein a ratio of the first diameter to the second diameter is approximately 6:1. 9. The heterojunction photovoltaic cell of claim 5 , wherein the layer of aluminum oxide is amorphous. 10. The heterojunction photovoltaic cell of claim 5 , wherein the substrate has a height of approximately 20 μm. 11. A synergistic method of capturing light in a heterojunction photovoltaic cell comprising an omnidirectional light trapping scheme, the method comprising the steps of: coating a graphene bilayer with an amount of gold chloride to dope the graphene bilayer; spin-coating a plurality of nonmetallic all-dielectric titania nanospheres onto the doped graphene bilayer; spin-coating a plurality of nonmetallic all-dielectric silica nanospheres onto the doped graphene bilayer including the nonmetallic dielectric titania nanospheres, forming a bilayer configuration of densely packed hexagonal arrays of nanospheres; wet etching the doped graphene bilayer including the nonmetallic all-dielectric titania nanospheres disposed beneath the nonmetallic dielectric silica nanospheres, wherein each nanosphere of the plurality of silica nanospheres, the plurality of titania nanosphere, or both are in physical contact with at least one alternative silica nanosphere, titania nanosphere, or both; transferring the doped graphene bilayer onto a silicon substrate to form the heterojunction photovoltaic cell; receiving and capturing an amount of light within the nonmetallic all-dielectric silica nanospheres; directing a portion of the amount of light into the nonmetallic all-dielectric titania nanospheres by forming whispering gallery modes within the nonmetallic all- dielectric silica nanoparticles, thereby reducing refraction loss; and directing the portion of the amount of light into the heterojunction photovoltaic cell. 12. The synergistic lossless omnidirectional light trapping scheme of claim 1 , wherein the inorganic omnidirectional bilayer configuration is configured to receive light having an angle of incidence of 0° to at most 60°. 13. The synergistic lossless omnidirectional light trapping scheme of claim 1 , wherein the reflected light is broadband in nature, whereby a reflectance of the light trapping scheme is at most 3% for a light spectrum ranging from at least 540 nm to at most 740 nm. 14. The synergistic lossless omnidirectional light trapping scheme of claim 1 , wherein