Inorganic paint pigment with plasmonic aluminum reflector layers and related methods

That which is claimed is: 1. An inorganic paint pigment comprising: a fluid matrix; and a plurality of paint flakes carried within the fluid matrix; each paint flake comprising a common aluminum layer having a first major surface and a second major surface opposing the first major surface, a first plasmonic aluminum reflector layer carried by the first major surface, and a second plasmonic aluminum reflector layer carried by the second major surface; each of the first plasmonic aluminum reflector layer and the second plasmonic aluminum reflector layer comprising an oxide layer over the common aluminum layer, and a layer of self-assembled aluminum particles over the oxide layer and having hybridized individual plasmonic modes to provide angle independent color, a gap between the common aluminum layer and the layer of self-assembled aluminum particles being less than 10 nm. 2. The inorganic paint pigment of claim 1 wherein the common aluminum layer comprises an aluminum mirror layer. 3. The inorganic paint pigment of claim 1 wherein the oxide layer comprises an aluminum oxide layer. 4. The inorganic paint pigment of claim 1 wherein plasmon resonance within each of the first plasmonic aluminum reflector layer and the second plasmonic aluminum reflector layer is independent to an angle of incidence for incident visible radiation. 5. The inorganic paint pigment of claim 1 wherein the fluid matrix comprises at least one of a solution and a polymer resin. 6. The inorganic paint pigment of claim 1 wherein the fluid matrix comprises a binder fluid. 7. The inorganic paint pigment of claim 1 wherein the fluid matrix comprises isopropyl alcohol (IPA). 8. The inorganic paint pigment of claim 1 wherein each paint flake is symmetric about the common aluminum layer. 9. An inorganic paint pigment comprising: a fluid matrix; and a plurality of paint flakes carried within the fluid matrix; each paint flake comprising a common aluminum mirror layer having a first major surface and a second major surface opposing the first major surface, a first plasmonic aluminum reflector layer carried by the first major surface, and a second plasmonic aluminum reflector layer carried by the second major surface, each of the first plasmonic aluminum reflector layer and the second plasmonic aluminum reflector layer comprising an oxide layer over the common aluminum mirror layer, and a layer of self-assembled aluminum particles over the oxide layer and having hybridized individual plasmonic modes to provide angle independent color, a gap between the common aluminum mirror layer and the layer of self-assembled aluminum particles being less than 10 nm, a wavelength of the angle independent color being based upon a diameter of the self-assembled aluminum particles. 10. The inorganic paint pigment of claim 9 wherein the oxide layer comprises an aluminum oxide layer. 11. The inorganic paint pigment of claim 9 wherein plasmon resonance within each of the first plasmonic aluminum reflector layer and the second plasmonic aluminum reflector layer is independent to an angle of incidence for incident visible radiation. 12. The inorganic paint pigment of claim 9 wherein the fluid matrix comprises at least one of a solution and a polymer resin. 13. The inorganic paint pigment of claim 9 wherein the fluid matrix comprises a binder fluid. 14. The inorganic paint pigment of claim 9 wherein the fluid matrix comprises isopropyl alcohol (IPA). 15. The inorganic paint pigment of claim 9 wherein each paint flake is symmetric about the common aluminum mirror layer. 16. A method for making an inorganic paint pigment comprising: forming a plasmonic aluminum reflector stack on a sacrificial polymer layer; and releasing the plasmonic aluminum reflector stack via a sonication step into a solvent and generating a plurality of paint flakes from the plasmonic aluminum reflector stack, each paint flake comprising a common aluminum layer having a first major surface and a second major surface opposing the first major surface, a first plasmonic aluminum reflector layer carried by the first major surface, and a second plasmonic aluminum reflector layer carried by the second major surface. 17. The method of claim 16 wherein the common aluminum layer comprises an aluminum mirror layer. 18. The method of claim 16 wherein each of the first plasmonic aluminum reflector layer and the second plasmonic aluminum reflector layer comprises an oxide layer over the common aluminum layer, and a layer of self-assembled aluminum particles over the oxide layer. 19. The method of claim 18 wherein the oxide layer comprises an aluminum oxide layer. 20. The method of claim 18 wherein plasmon resonance within each of the first plasmonic aluminum reflector layer and the second plasmonic aluminum reflector layer is independent to an angle of incidence for incident visible radiation. 21. The method of claim 16 wherein each paint flake is symmetric about the common aluminum layer. 22. The inorganic paint pigment of claim 1 wherein a wavelength of the angle independent color is based upon a diameter of the self-assembled aluminum particles.