Polarization rotator for silicon photonics

What is claimed is: 1. A photonic waveguide structure for performing polarization rotation, the structure comprising: a first waveguide layer including input and output waveguides, the input and output waveguides being separate and discontinuous structures, the input and output waveguides being configured in the first waveguide layer such that respective centerlines of the input and output waveguides have a lateral offset therebetween; and a second waveguide layer comprising a waveguide structure disposed under or over the first waveguide layer, the waveguide structure including a polarization conversion region configured within the second waveguide layer to overlap the input or output waveguides in the first waveguide layer. 2. The photonic waveguide structure of claim 1 , wherein each of at least a portion of the input and output waveguides in the first waveguide layer and the waveguide structure in the second waveguide layer comprises at least one of silicon (Si), silicon nitride (SiN), silicon oxynitride (SiON), polysilicon, and at least one polymer. 3. The photonic waveguide structure of claim 2 , wherein the at least one polymer is transparent in a prescribed wavelength region of interest. 4. The photonic waveguide structure of claim 2 , wherein the at least one polymer comprises at least one of poly(methyl methacrylate), amorphous fluoropolymer, polystyrene and SU-8 epoxy-based negative photoresist. 5. The photonic waveguide structure of claim 1 , wherein at least one of an input and an output of the waveguide structure in the second waveguide layer is formed having a taper structure for transitioning an input wave supplied to the photonic waveguide structure between the first and second waveguide layers. 6. The photonic waveguide structure of claim 5 , wherein a length of the taper structure forming the output of the waveguide structure in the second waveguide layer is varied to maximize a transverse mode conversion efficiency of the photonic waveguide structure. 7. The photonic waveguide structure of claim 5 , wherein a length of a taper structure forming the input of the waveguide structure in the second waveguide layer is the same as a length of a taper structure forming the output of the waveguide structure. 8. The photonic waveguide structure of claim 1 , wherein the second waveguide layer is configured as both a transition waveguide and a propagating waveguide. 9. The photonic waveguide structure of claim 1 , wherein the first and second waveguide layers are separated from one another by a gap of a prescribed dimension. 10. The photonic waveguide structure of claim 9 , wherein a size of the gap is configured such that it is small enough that light couples from one of the first and second waveguide layers to another of the first and second waveguide layers within a prescribed distance, and large enough so as not to incur losses in beginning and ending regions of the first and second waveguide layers. 11. The photonic waveguide structure of claim 9 , wherein a size of the gap is about 0.1 micron. 12. The photonic waveguide structure of claim 9 , wherein a size of the gap is in a range of about greater than zero to 0.25 micron. 13. The photonic waveguide structure of claim 1 , wherein the lateral offset between the input and output waveguides in the first waveguide layer is in a range between about 0.25 micron and 0.30 micron. 14. A method of fabricating a polarization rotator structure for use in a polarization diversity circuit (PDC) of a silicon-based optical waveguide, the method comprising: forming input and output waveguides in a first waveguide layer, the input and output waveguides being configured as separate and discontinuous structures, with respective centerlines of the input and output waveguides having a lateral offset therebetween; and forming a waveguide structure in a second waveguide layer, the waveguide structure being disposed under or over the first waveguide layer, the waveguide structure including a polarization conversion region configured within the second waveguide layer to overlap the input or output waveguides in the first waveguide layer. 15. The method of claim 14 , further comprising configuring the second waveguide layer as both a transition waveguide and a propagating waveguide. 16. The method of claim 14 , further comprising separating the first and second waveguide layers from one another by a gap of a prescribed dimension. 17. The method of claim 16 , further comprising configuring a size of the gap so that it is small enough that light couples from one of the first and second waveguide layers to another of the first and second waveguide layers within a prescribed distance, and large enough so as not to incur losses in beginning and ending regions of the first and second waveguide layers. 18. The method of claim 14 , further comprising forming at least one of an input and an output of the waveguide structure in the second waveguide layer to have a taper structure for transitioning an input wave supplied to the photonic waveguide structure between the first and second waveguide layers. 19. The method of claim 18 , further comprising varying a length of the taper structure forming the output of the waveguide structure in the second waveguide layer so as to increase a transverse mode conversion efficiency of the photonic waveguide structure. 20. The method of claim 18 , further comprising configuring a length of the taper structure forming the input of the waveguide structure in the second waveguide layer so that it is the same as a length of the taper structure forming the output of the waveguide structure.