High index contrast grating structure for light manipulation and related method

The invention claimed is: 1. A high index contrast grating (HICG) structure comprising: a plurality of gratings fabricated from a high refractive index layer, said plurality of gratings including a first grating, a second grating adjacent said first grating, and a third grating adjacent said second grating such that said second grating is situated between said third grating and said first grating; wherein said high refractive index layer is situated over a low refractive index substrate; and wherein said high refractive index layer is patterned after determining a combination of a period, a thickness, and a duty cycle of each of said plurality of gratings for a desired reflection phase profile; said combination being determined for said first grating based on a lookup table; said combination being determined for said second grating using a location and a period of said first grating and based on said lookup table; and said combination being determined for said third grating using a location and a period of said second grating and based on said lookup table. 2. The HICG structure of claim 1 , wherein said low refractive index substrate includes silicon nitride. 3. The HICG structure of claim 1 , wherein at least one of said plurality of gratings includes amorphous silicon. 4. The HICG structure of claim 1 , wherein at least one of said plurality of gratings includes polycrystalline silicon. 5. The HICG structure of claim 1 , wherein said high refractive index layer has a refractive index at least two times greater than that of said low refractive index substrate. 6. The HICG structure of claim 1 , wherein said HICG structure includes subwavelength gratings for incident wavelengths of equal to or greater than 2.5 microns. 7. The HICG structure of claim 1 , wherein said HICG structure functions as a combinatory optical system having multiple components on said low refractive index substrate. 8. The HICG structure of claim 1 , wherein said HICG structure is a mid-infrared reflective mirror having a reflectivity of approximately 100%. 9. The HICG structure of claim 1 , wherein said HICG structure has a reflection phase profile of a blazed grating. 10. The HICG structure of claim 1 , wherein said HICG structure has a reflection phase profile of a focusing reflector. 11. A method of forming a high index contrast grating (HICG) structure, said method comprising: providing a lookup table containing transmissivity and/or reflectivity data corresponding to pre-determined wavelengths; forming a high refractive index layer over a low refractive index substrate; determining a combination of a period, a thickness, and a duty cycle of each of a plurality of gratings for a desired transmission or reflection profile, said plurality of gratings including a first grating, a second grating adjacent said first grating, and a third grating adjacent said second grating such that said second grating is situated between said third grating and said first grating; wherein determining said combination for said first grating is performed based on said lookup table; wherein determining said combination for said second grating is performed using a location and a period of said first grating and based on said lookup table; wherein determining said combination for said third grating is performed using a location and a period of said second grating and based on said lookup table; and patterning said high refractive index layer to form said plurality of gratings. 12. The method of claim 11 , wherein said transmissivity and/or reflectivity data includes transmissivity and/or reflectivity phase data. 13. The method of claim 11 , wherein said transmissivity and/or reflectivity data includes transmissivity and/or reflectivity amplitude data. 14. The method of claim 11 , wherein said HICG structure is configured to transmit a wave through said HICG structure, such that said HICG structure functions as a focusing lens, a divergence lens, or a high numerical aperture lens. 15. The method of claim 11 , wherein said HICG structure is configured to transmit a wave through said HICG structure, such that said transmitted wave has amplitude and phase profiles of a diffraction grating. 16. The method of claim 11 , wherein said HICG structure is configured to reflect a wave, such that said HICG structure functions as a concave mirror, a convex mirror, a focusing lens, or a divergence lens. 17. The method of claim 11 , wherein said HICG structure is configured to reflect a wave, such that said reflected wave has amplitude and phase profiles of a diffraction grating. 18. The method of claim 11 , wherein said HICG structure is a mid-infrared reflective mirror having a reflectivity of approximately 100%. 19. The method of claim 11 , wherein said HICG structure is configured to reflect a wave, such that said reflected wave has amplitude and phase profiles of a blazed grating. 20. The method of claim 11 , wherein said HICG structure includes subwavelength gratings for incident wavelengths of equal to or greater than 2.5 microns.