Silicon photonics alignment tolerant vertical grating couplers

What is claimed is: 1. An optoelectronic integrated circuit structure comprising: an insulator layer; a semiconductor core of a first optical waveguide on said insulator layer; an isolation region on said insulator layer laterally surrounding said semiconductor core, said isolation region comprising a first dielectric material; a dielectric core of a second optical waveguide, said dielectric core comprising: at least one layer of a second dielectric material, said second dielectric material being different from said first dielectric material and said at least one layer of said second dielectric material having a first section above an end of said semiconductor core and a second section above said isolation region; and, a stack of dielectric layers above said first section and extending laterally onto said second section; and, a grating coupler comprising multiple dielectric fins above said second section and positioned laterally adjacent to said stack, said dielectric fins being perpendicularly oriented relative to said stack and said end of said semiconductor core, said stack and each of said dielectric fins comprising a layer of said first dielectric material and additional layers of said second dielectric material above said layer of said first dielectric material. 2. The optoelectronic integrated circuit structure of claim 1 , said semiconductor core comprising silicon, said first dielectric material comprising silicon dioxide and said second dielectric material comprising silicon nitride. 3. The optoelectronic integrated circuit structure of claim 1 , said additional layers of said second dielectric material comprising four additional layers of said second dielectric material, and said optoelectronic integrated circuit structure further comprising a blanket layer of a third dielectric material over said stack and said dielectric fins, said third dielectric material being different from said first dielectric material and said second dielectric material. 4. The optoelectronic integrated circuit structure of claim 1 , said additional layers of said second dielectric material comprising two additional layers of said second dielectric material, said dielectric core further comprising a portion of at least one conformal layer of said second dielectric material that covers said stack, said at least one conformal layer of said second dielectric material further covering said dielectric fins, and said optoelectronic integrated circuit structure further comprising a blanket layer of a third dielectric material on said at least one conformal layer of said second dielectric material, said third dielectric material being different from said first dielectric material and said second dielectric material. 5. The optoelectronic integrated circuit structure of claim 1 , wherein at least one of said end of said semiconductor core and an adjacent end of said dielectric core is tapered. 6. The optoelectronic integrated circuit structure of claim 1 , further comprising a signal propagation termination region comprising a trench that extends vertically through said stack to said at least one layer of said second dielectric material, said trench being filled with a third dielectric material that is different from said first dielectric material and said second dielectric material. 7. An optoelectronic integrated circuit structure comprising: an insulator layer; a semiconductor core of a first optical waveguide on said insulator layer; a grating coupler on said insulator layer adjacent to an end of said semiconductor core, said grating coupler comprising multiple semiconductor fins that are perpendicularly oriented relative to said end of said semiconductor core and that are shorter than said semiconductor core; an isolation region on said insulator layer laterally surrounding said semiconductor core and each of said fins and further covering said fins, said isolation region comprising a first dielectric material; a dielectric core of a second optical waveguide, said dielectric core comprising multiple dielectric layers above said end of said semiconductor core and extending laterally over said isolation region and said semiconductor fins within said isolation region, said multiple dielectric layers comprising: at least one layer of a second dielectric material different from said first dielectric material; a layer of said first dielectric material above said at least one layer of said second dielectric material; and, additional layers of said second dielectric material above said layer of said first dielectric material. 8. The optoelectronic integrated circuit structure of claim 7 , said semiconductor core comprising silicon, said first dielectric material comprising silicon dioxide and said second dielectric material comprising silicon nitride. 9. The optoelectronic integrated circuit structure of claim 7 , said additional layers of said second dielectric material comprising at least two additional layers of said second dielectric material, and said optoelectronic integrated circuit structure further comprising a blanket layer of a third dielectric material over said multiple dielectric layers, said third dielectric material being different from said first dielectric material and said second dielectric material. 10. The optoelectronic integrated circuit structure of claim 7 , wherein at least one of said end of said semiconductor core and an adjacent end of said dielectric core is tapered. 11. The optoelectronic integrated circuit structure of claim 7 , further comprising a signal propagation termination region comprising a trench that extends vertically through said multiple dielectric layers to said at least one layer of said second dielectric material, said trench being filled with a third dielectric material that is different from said first dielectric material and said second dielectric material. 12. A method of forming an optoelectronic integrated circuit structure, said method comprising: forming an opening in at least one protective layer so as to expose an end of a semiconductor core for a first optical waveguide and an isolation region adjacent to said end, said isolation region comprising a first dielectric material; depositing multiple dielectric layers over said at least one protective layer and in said opening, said multiple dielectric layers comprising: at least one layer of a second dielectric material, said second dielectric material being different from said first dielectric material and said at least one layer of said second dielectric material having a first section above said end of said semiconductor core and a second section above said isolation region; a layer of said first dielectric material on said at least one layer of said second dielectric material; and, additional layers of said second dielectric material on said layer of said first dielectric material; and, forming a trench in said multiple dielectric layers within said opening such that said trench extends vertically to said at least one layer of said second dielectric material, such that said trench defines, for a dielectric core of a second optical waveguide, a stack of dielectric layers above said first section and extending laterally onto said second section and such that said trench further defines, for a grating coupler, multiple dielectric fins above said second section and positioned laterally adjacent to said stack, said multiple dielectric fins being essentially perpendicularly oriented relative to said stack and said end of said semiconductor core. 13. The method of claim 12 , said semiconductor core comprising silicon, said first dielectric material comprising silico