See-through reflective metasurface

The invention claimed is: 1. A see-through reflective optical device comprising: a reflective metasurface configured for a targeted design optical wavelength, wherein the reflective metasurface comprises a sub-wavelength periodic arrangement of meta-atoms formed by patterned isolated gap surface plasmon (GSP) resonators, where the patterned isolated GSP resonators comprise a patterned optically thin metal layer for the design wavelength, an optically thick metal layer for the design wavelength, and an insulator layer between the patterned optically thin metal layer and the optically thick metal layer; and an array of apertures of random positions and diameters greater than the targeted design wavelength formed through the reflective metasurface providing a designed percentage of light transparency through the reflective metasurface. 2. The see-through reflective optical device of claim 1 , wherein the reflective metasurface comprises a reflective diffraction grating metasurface. 3. The see-through reflective optical device of claim 2 , wherein the reflective diffraction grating metasurface is at least partially defined by a periodic arrangement of unit cells, wherein each unit cell having a plurality of meta-atoms. 4. The see-through reflective optical device of claim 3 , wherein at least two of the meta-atoms in a unit cell have different length to width ratios. 5. The see-through reflective optical device of claim 1 , wherein the patterned optically thin metal layer and the optically thick metal layer comprise silver. 6. The see-through reflective optical device of claim 5 , wherein the patterned optically thin metal layer has a thickness of less than 40 nm. 7. The see-through reflective optical device of claim 1 , wherein the targeted design optical wavelength is in the range from 400-750 nm. 8. The see-through reflective optical device of claim 1 , wherein the patterned insulator layer comprises SiO 2 . 9. The see-through reflective optical device of claim 7 , wherein the array of apertures of random positions and diameters comprises circular apertures each of a random diameter varying between at least two times the target design wavelength and 60 μm positioned at random non-intersecting positions. 10. The see-through reflective optical device of claim 7 , wherein the array of apertures of random positions and diameters comprises circular apertures each of a random radius varying between 8 μm and 30 μm positioned at random non-intersecting positions. 11. The see-through reflective optical device of claim 7 , wherein a sum of the area of all apertures of the array of apertures of random positions and diameters provides a design transparency percentage of visible light of 10-90% through the metasurface diffraction grating. 12. The see-through reflective optical device of claim 1 , wherein the device is a combiner that combines two images from two different sides of the combiner. 13. A near eye display assembly comprising (a) frame; (b) a combiner operably connected to the frame as a first reflective surface positionable in front of an eye of a user of the display assembly; (c) a secondary mirror operably connected to the frame as a second reflective surface positionable proximate a side of the nose adjacent to the eye of a user of the display assembly; (d) an image source operably connected to the frame and optically coupled to the secondary mirror along an optical path; and (e) an optical fold element between the image source and the secondary mirror in the optical path, and positionable proximate the temple adjacent to the eye of a user of the display assembly; wherein the combiner and the secondary are in a folded geometry which directs images from the optical fold element to an eyebox of the near eye display assembly, and wherein the combiner comprises a see-through reflective optical device according to claim 1 , which provides wavefront control of a reflected image from the image source which combines the reflected image with an image transmitted through the combiner. 14. The near eye display assembly of claim 13 , wherein the reflective metasurface of the see-through reflective optical device comprises a reflective diffraction grating metasurface which is at least partially defined by a periodic arrangement of unit cells, wherein each unit cell having a plurality of meta-atoms, and wherein at least two of the meta-atoms in a unit cell have different length to width ratios. 15. The near eye display assembly of claim 14 , wherein the targeted design optical wavelength of the see-through reflective optical device of is in the range from 400-750 nm. 16. The near eye display assembly of claim 15 , wherein the array of apertures of random positions and diameters of the see-through reflective optical device comprises circular apertures each of a random diameter varying between at least two times the target design wavelength and 60 μm positioned at random non-intersecting positions. 17. The near eye display assembly of claim 15 , wherein the array of apertures of random positions and diameters of the see-through reflective optical device comprises circular apertures each of a random radius varying between 8 μm and 30 μm positioned at random non-intersecting positions. 18. The near eye display assembly of claim 15 , wherein a sum of the area of all apertures of the array of apertures of random positions and diameters of the see-through reflective optical device provides a design transparency percentage of visible light of 10-90% through the metasurface diffraction grating. 19. The see-through reflective optical device of claim 1 , wherein the array of apertures of random positions and diameters comprises circular apertures each of a random radius varying between 8 μm and 30 μm positioned at random non-intersecting positions. 20. The see-through reflective optical device of claim 1 , wherein a sum of the area of all apertures of the array of apertures of random positions and diameters provides a design transparency percentage of visible light of 10-90% through the metasurface diffraction grating.