Integrated photonics mode splitter and converter

What is claimed is: 1. A system comprising: a substrate layer having a first index of refraction; and a waveguide layer formed on the substrate layer, the waveguide layer having a second index of refraction different from the first index of refraction, wherein the waveguide layer comprises: one or more waveguides formed therein of a material having a third index of refraction, wherein at least one waveguide in the one or more waveguides comprises a modulated sidewall; and one or more ports for receiving one or more input photons and providing one or more output photons, where an output mode of the one or more output photons and a port in the one or more ports associated with the one or more output photons is based on an input mode of the one or more input photons; wherein the one or more waveguides and the one or more ports from a mode converter, the mode converter comprising: the port in the one or more ports configured to receive a photon propagating in a first mode; and a waveguide coupled to the port that causes the photon to output through the port propagating in an orthogonal mode to the first mode, wherein the waveguide comprises a first periodically modulated sidewall and a second periodically modulated sidewall, wherein modulation of the first periodically modulated sidewall and the second periodically modulated sidewall are out of phase with one another such that a transverse cross-sectional profile of the waveguide has a constant height and width along a length of the waveguide. 2. The system of claim 1 , wherein the one or more waveguides and the one or more ports include additional ports and additional waveguides to form a mode splitter, the mode splitter comprising: a first waveguide in the additional waveguides coupled to an input port and a first output port in the additional ports, wherein the first waveguide receives a first photon and a second photon through the input port and provides the first photon to the first output port; and a second waveguide in the one or more waveguides coupled to a second output port in the one or more ports, wherein the second photon is coupled into the second waveguide and output through the second output port. 3. The system of claim 2 , wherein a wall of the second waveguide proximate to the first waveguide is modulated. 4. A device comprising: a substrate layer having a first index of refraction; and a waveguide layer formed on the substrate layer, the waveguide layer having a second index of refraction different from the first index of refraction, wherein the waveguide layer comprises: one or more ports for receiving one or more input photons and providing one or more output photons, where an output mode of the one or more output photons and a port in the one or more ports associated with the one or more output photons is based on an input mode of the one or more input photons, wherein the port receives a photon propagating in a first mode; and one or more waveguides formed therein of a material having a third index of refraction, wherein at least one waveguide in the one or more waveguides comprises one or more modulated sidewalls, wherein a mode converting waveguide in the one or more waveguides is coupled to the port configured to receive a photon propagating in the first mode, the mode converting waveguide having a first periodically modulated sidewall and a second periodically modulated sidewall, wherein modulation of the first periodically modulated sidewall and the second periodically modulated sidewall are out of phase with one another such that a transverse cross-sectional profile of the mode converting waveguide has a constant height and width along a length of the mode converting waveguide, wherein the first periodically modulated sidewall and the second periodically modulated sidewall cause the photon to output through the port propagating in an orthogonal mode to the first mode. 5. The device of claim 4 , wherein the substrate layer is formed from a first material that is periodically poled potassium titanyl phosphate. 6. The device of claim 4 , wherein the waveguide layer is formed from a second material that is silicon nitride. 7. The device of claim 4 , wherein the first mode is a TE mode. 8. A system comprising: a substrate having a first index of refraction; and a waveguide layer on the substrate, wherein the waveguide layer has a second index of refraction different from the first index of refraction with waveguides formed therein of a material having a third index of refraction, the waveguide layer comprising: one or more mode splitters that receive at least one of a first photon in a first mode and a second photon in a second mode through an input port and provide at least one of the first photon through a first output port and the second photon through a second output port; and a mode converter coupled to the second output port of a mode splitter in the one or more mode splitters, wherein the mode converter receives the second photon through a port and outputs the second photon in the first mode through the port, wherein the mode converter comprises a waveguide coupled to the port that causes the second photon to output through the port propagating in the first mode, wherein the waveguide comprises a first modulated sidewall and a second modulated sidewall, wherein the first modulated sidewall is out of phase with the second modulated sidewall such that a transverse cross-sectional profile of the waveguide has a constant height and width along a length of the waveguide. 9. The system of claim 8 , wherein the mode splitter in the one or more mode splitters comprises: a first waveguide coupled to the input port and the first output port; and a second waveguide coupled to the second output port, wherein the second photon is coupled into the second waveguide from the first waveguide and output through the second output port. 10. The system of claim 9 , wherein a wall of the second waveguide proximate to the first waveguide is a modulated sidewall.