All-optical logic gates and methods for their fabrication

The invention claimed is: 1. An optical device, comprising one or more input ports for receiving one or more input optical signals, an interferometric component in optical coupling with at least one of said input ports to receive at least one signal based on said input signals and to generate at least two intermediate signals from said at least one received signal, said interferometric component having one or more nano-sized waveguides formed of a material exhibiting nonlinearity for providing propagation paths for said at least two intermediate signals such that said intermediate signals accumulate phase asymmetrically upon propagation through said one or more nano-sized waveguides, said interferometric component being configured to generate an output signal based on interference of said intermediate signals subsequent to their asymmetric phase accumulation, and an output port in optical coupling with said interferometer to receive said output signal, an optical gain mechanism coupled to at least one of said one or more nano-sized waveguides for providing an optical gain profile exhibiting an asymmetric optical gain for at least one wavelength corresponding to a wavelength of at least one of said derived signals, wherein said optical gain mechanism comprises: a gain medium disposed in said at least one nano-sized waveguide, and an optical source for generating a pump radiation, said optical source being optically coupled to a portion of said at least one waveguide to deliver said pump radiation to the gain medium, said optical pulse having a wavelength suitable for absorption by said gain medium, wherein said gain medium is uniformly distributed along said loop. 2. The optical device of claim 1 , wherein said pump pulse asymmetrically excites said gain medium as it propagates along the loop. 3. An optical device, comprising: one or more input ports for receiving one or more input optical signals, an interferometric component in optical coupling with at least one of said input ports to receive at least one signal based on said input signals and to generate at least two intermediate signals from said at least one received signal, said interferometric component having one or more nano-sized waveguides formed of a material exhibiting nonlinearity for providing propagation paths for said at least two intermediate signals such that said intermediate signals accumulate phase asymmetrically upon propagation through said one or more nano-sized waveguides, said interferometric component being configured to generate an output signal based on interference of said intermediate signals subsequent to their asymmetric phase accumulation, and an output port in optical coupling with said interferometer to receive said output signal, wherein said one or more nano-sized waveguides are substantially transparent to radiation wavelengths in a range of about 400 nm to about 1000 nm. 4. The optical device of claim 3 , wherein said one or more nano-sized waveguides are substantially transparent to radiation having wavelengths in a range of about 800 nm to about 1550 nm. 5. The optical device of claim 3 , further comprising optical gain mechanism coupled to at least one of said one or more nano-sized waveguides for providing an optical gain profile exhibiting an asymmetric optical gain for at least one wavelength corresponding to a wavelength of at least one of said derived signals. 6. The optical device of claim 5 , wherein said optical gain mechanism comprises: a gain medium disposed in said at least one nano-sized waveguide, and an optical source for generating a pump radiation, said optical source being optically coupled to a portion of said at least one waveguide to deliver said pump radiation to the gain medium, said optical pulse having a wavelength suitable for absorption by said gain medium. 7. The optical device of claim 3 , wherein said one or more nano-sized waveguides are formed of a material exhibiting a third order nonlinear susceptibility (χ 3 ) greater than about 10 −14 cm 2 /W. 8. The optical device of claim 3 , wherein said one or more nano-sized waveguides is formed of TiO 2 . 9. The optical device of claim 3 , wherein said interferometric component has a Sagnac configuration and said one or more nano-sized waveguides comprise a waveguide loop. 10. The optical device of claim 9 , wherein said waveguide loop has an input port and an output port, said input and output ports of the loop being evanescently coupled to split said at least one received signal into a CW propagating signal and a CCW propagating signal corresponding to said intermediate signals. 11. The optical device of claim 10 , wherein at least one of said counter-propagating signals accumulates phase non-linearly as a result of self phase modulation. 12. The optical device of claim 10 , wherein said evanescent coupling is characterized by a coupling coefficient less than about 0.5. 13. The optical device of claim 12 , wherein said waveguide loop has a width in a range of about 100 nm to about 500 nm. 14. The optical device of claim 9 , wherein said waveguide loop has a width less than about 500 nm. 15. The optical device of claim 9 , wherein said evanescent coupling is characterized by a coupling coefficient in a range of about 0.3 to about 0.5. 16. The optical device of claim 3 , wherein said interferometric component has a Mach-Zehnder interferometric configuration and said one or more nano-sized waveguides comprise two waveguide branches of said Mach-Zehnder interferometric configuration. 17. The optical device of claim 16 , wherein said two waveguide branches are coupled at an input junction configured to split said at least one received signal into said at least two intermediate signals and are coupled at an output junction for combining said intermediate signal subsequent to their asymmetric phase accumulation to generate said output signal. 18. The optical device of claim 3 , further comprising a semiconductor substrate on which said interferometric component is disposed. 19. The optical device of claim 18 , further comprising an insulating layer separating said interferometer component from said substrate. 20. The optical device of claim 19 , wherein said substrate comprises a silicon substrate and said insulating layer comprises a silicon oxide layer. 21. The optical device of claim 3 , further comprising any of a loss, a gain, a dispersive mechanism or a control signal coupled to at least one of said one or more nano-sized waveguides so as to facilitate said asymmetric phase accumulation of said optical signals. 22. The optical device of claim 21 , wherein said loss mechanism comprises a cladding layer disposed over a selected portion of said at least one of said one or more nano-sized waveguides. 23. The optical device of claim 21 , wherein said loss mechanism comprises a light scattering mechanism. 24. The optical device of claim 3 , wherein said interferometric component has a Michelson interferometric configuration and said one or more nano-sized waveguides comprise two branches of the Michelson configuration. 25. The optical device of claim 3 , wherein said optical device comprises an optical logic circuit and wherein said one or more input optical signals represent one or more logic signals and said output signal represents a Boolean logic applied to said one or more input logic signals. 26. The optical device of clai