Two-stage adiabatically coupled photonic systems

What is claimed is: 1. A photonic system comprising a silicon (Si) photonic integrated circuit (PIC) polarization splitter or combiner, wherein the Si PIC polarization splitter or combiner comprises: a first silicon nitride (SiN) waveguide formed in a first layer of a silicon (Si) photonic integrated circuit (PIC); a second SiN waveguide formed in the first layer of the Si PIC, wherein the second SiN waveguide is laterally spaced apart from and extends parallel to the first SiN waveguide; and a first Si waveguide, formed in a second layer of the Si PIC, the first Si waveguide including a first tapered end, an S-bend, and a second tapered end, wherein the first tapered end is positioned near a first end of the first SiN waveguide and is adiabatically coupled to the first end of the first SiN waveguide, the second tapered end is positioned near a first end of the second SiN waveguide and is adiabatically coupled to the first end of the second SiN waveguide, and the S-bend is positioned between the first tapered end and the second tapered end; wherein a tip width of the first tapered end of the first Si waveguide is narrower than a TE maximum taper width to permit adiabatic coupling of TE polarization of light between the first SiN waveguide and the first Si waveguide with high efficiency relative to a coupling efficiency of TM polarization of light and is wider than a TM maximum taper width above which prevents adiabatic coupling of the TM polarization of light between the first SiN waveguide and the first Si waveguide with high efficiency relative to coupling efficiency of the TE polarization; and wherein a tip width of the second tapered end of the Si waveguide is narrower than the TE maximum taper width to permit adiabatic coupling of the TE polarization of light between the first Si waveguide and the second SiN waveguide with high efficiency relative to the coupling efficiency of the TM polarization and is wider than the TM maximum taper width above which prevents adiabatic coupling of the TM polarization of light between the first Si waveguide and the second SiN waveguide with high efficiency relative to the coupling efficiency of the TE polarization. 2. The photonic system of claim 1 , wherein: the Si PIC polarization splitter or combiner comprises the Si PIC polarization splitter, the first end of the first SiN waveguide comprises an input end of the first SiN waveguide and the first end of the second SiN waveguide comprises an input end of the second SiN waveguide; and TE polarization input to the first SiN waveguide is substantially directed to the second SiN waveguide and TM polarization input to the first SiN waveguide substantially remains in the first SiN waveguide to obtain a desired ratio of optical power in TE polarization relative to optical power in TM polarization at an output end of each of the first and second SiN waveguides that is opposite the input end of each of the first and second SiN waveguides. 3. The photonic system of claim 2 , wherein: the Si PIC polarization splitter further comprises a second Si waveguide including a first tapered end near the output end of the first SiN waveguide and adiabatically coupled to the first SiN waveguide; a tip width of the first tapered end of the second Si waveguide is narrower than the TE maximum taper width that permits adiabatic coupling of the TE polarization of light from the first SiN waveguide to the second Si waveguide with high efficiency relative to the coupling efficiency of the TM polarization and is wider than the TM maximum taper width above which prevents adiabatic coupling of the TM polarization of light from the first SiN waveguide to the second Si waveguide with high efficiency relative to the coupling efficiency of the TE polarization; in order that any TE polarization of light remaining in the first SiN waveguide after the first tapered end of the first Si waveguide and near the output of the first SiN waveguide is substantially directed away from the first SiN waveguide to the second Si waveguide and the TM polarization in the first SiN waveguide substantially remains in the first SiN waveguide to obtain the desired ratio of optical power in the TE polarization relative to optical power in the TM polarization. 4. The photonic system of claim 2 , wherein in a direction from the first tapered end to the second tapered end of the first Si waveguide: a width of the first tapered end of the first Si waveguide tapers from the tip width, which is in a range between 130 nanometers and 180 nanometers, up to a maximum width of about 320 nanometers in a region of overlap of the first tapered end of the first Si waveguide with the first SiN waveguide; and a width of the second tapered end of the first Si waveguide tapers from a maximum width of about 320 nanometers down to the tip width, which is in the range between 130 nanometers and 180 nanometers, in a region of overlap of the second tapered end of the first Si waveguide with the second SiN waveguide. 5. The photonic system of claim 2 , wherein: 80% or more of the TM polarization of the input beam remains in the first SiN waveguide after the coupler portion of the first SiN waveguide; and 90% or more of the TE polarization of the input beam is coupled by the Si PIC polarization splitter from the first SiN waveguide to the second SiN waveguide. 6. The photonic system of claim 1 , wherein the tip width of each of the first and second tapered ends is in a range between 130 nanometers and 180 nanometers. 7. The photonic system of claim 2 , further comprising: a first wavelength division demultiplexer (WDM demux) formed in the first layer of the Si PIC, wherein the first WDM demux includes a plurality of outputs and an input optically coupled to a second end of the first SiN waveguide that is opposite the first end of the first SiN waveguide; wherein the first WDM demux is designed to separate a plurality of wavelength channels having TM polarization at its input each to a set of outputs, each corresponding to one of the wavelength channels; and a second WDM demux formed in the first layer of the Si PIC, wherein the second WDM demux includes a plurality of outputs and an input optically coupled to a second end of the second SiN waveguide that is opposite the first end of the second SiN waveguide; wherein the second WDM demux is designed to separate a plurality of wavelength channels having TE polarization at its input each to a set of outputs, each corresponding to one of the wavelength channels. 8. The photonic system of claim 2 , further comprising: a polarization rotator disposed in an optical path between the second end of the first SiN waveguide and an input of a first wavelength division demultiplexer (WDM demux) formed in the first layer of the Si PIC, wherein the first WDM demux includes a plurality of outputs; wherein the first WDM demux is designed to separate a plurality of wavelength channels having TE polarization at its input each to a set of outputs, each corresponding to one of the wavelength channels; and a second WDM demux formed in the first layer of the Si PIC, wherein the second WDM demux includes a plurality of outputs and an input optically coupled to a second end of the second SiN waveguide that is opposite the first end of the second SiN waveguide; wherein the second WDM demux designed to separate a plurality of wavelength channels having TE polarization at its input each to a set of outputs, each corresponding to one of the wavelength channels. 9. The photonic system of claim 8 , wherein each of the first and second WDM demuxes comprises an Echelle grating. 10. A photonic system comprising a silicon (Si) photonic integrated circuit (PIC) polarization