Arrays of integrated analytical devices and methods for production

What is claimed is: 1. An analytical system for the simultaneous measurement of multiple reactions comprising: an array of integrated analytical devices; and an excitation light source; wherein the array of integrated analytical devices comprises: a substrate layer; a filter module layer disposed on the substrate layer; a collection module layer disposed on or with the filter module layer, wherein the collection module layer comprises a Fresnel lens structure configured to split a light beam into a plurality of light beams; a waveguide module layer disposed on the collection module layer; and a zero-mode waveguide module layer disposed on the waveguide module layer; wherein the zero-mode waveguide module layer comprises a plurality of nanometer-scale apertures penetrating into the waveguide module layer. 2. The analytical system of claim 1 , wherein the substrate layer is a detector layer. 3. The analytical system of claim 2 , wherein the detector layer comprises a color-separation layer. 4. The analytical system of claim 1 , wherein the substrate layer is a CMOS wafer. 5. The analytical system of claim 1 , wherein the filter module layer comprises a dielectric filter. 6. The analytical system of claim 1 , wherein the filter module layer comprises an absorptive filter. 7. The analytical system of claim 1 , wherein the plurality of nanometer-scale apertures is formed by etching, and the etching is stopped using an endpoint signal. 8. The analytical system of claim 1 , wherein the waveguide module layer comprises an upper cladding of waveguide cladding material disposed on a waveguide core material, and at least one nanometer-scale aperture fully penetrates the upper cladding of waveguide cladding material into the waveguide core material. 9. The analytical system of claim 8 , wherein the at least one nanometer-scale aperture is partially backfilled. 10. The analytical system of claim 9 , wherein the at least one nanometer-scale aperture is partially backfilled using atomic layer deposition or low pressure chemical vapor deposition. 11. The analytical system of claim 8 , wherein the upper cladding of waveguide cladding material is SiO 2 . 12. The analytical system of claim 8 , wherein the waveguide core material is Si 3 N 4 . 13. The analytical system of claim 8 , further comprising an etch hardmask disposed between the waveguide core material and the upper cladding of waveguide cladding material. 14. The analytical system of claim 1 , wherein at least one nanometer-scale aperture comprises a fluid sample comprising a fluorescent species. 15. The analytical system of claim 14 , wherein the fluorescent species is a fluorescently labeled nucleotide analog. 16. The analytical system of claim 1 , wherein the plurality of nanometer-scale apertures comprise at least 100 nanometer-scale apertures. 17. The analytical system of claim 1 , wherein the plurality of nanometer-scale apertures have a density of at least 1000 apertures per cm 2 . 18. The array of claim 1 , wherein the Fresnel lens structure is a diffractive Fresnel lens structure. 19. The analytical system of claim 1 , wherein the Fresnel lens structure is a refractive Fresnel lens structure. 20. The analytical system of claim 1 , wherein the Fresnel lens structure combines refractive and diffractive features. 21. The analytical system of claim 1 , wherein the Fresnel lens structure is a phase Fresnel zone plate. 22. The analytical system of claim 21 , wherein the Fresnel lens structure is at least a two-phase Fresnel zone plate. 23. The analytical system of claim 21 , wherein the Fresnel lens structure is at least a four-phase Fresnel zone plate. 24. The analytical system of claim 1 , wherein the excitation light source is coupled to the array of integrated analytical devices through an optical coupler integrated in the array. 25. The analytical system of claim 1 , wherein the array of integrated analytical devices further includes an alignment feature.