Topological insulator laser system

The invention claimed is: 1. A laser system comprising: an array of optical elements configured as optical resonators comprising optical resonators comprising gain material, the optical resonators of the array are optically coupled between them and are spatially arranged supporting at least one topological mode associated with certain spatial region of the array, said array comprising at least two optical links coupling between said optical resonators of the array, said optical links being accommodated with selected spatial shifts with respect to an axis between corresponding optical resonators, said shifts varying between different rows of the array, thereby providing phase difference associated with two optical paths connecting said optical resonators through the links; a pumping unit configured to provide pumping of a group of the optical resonators of the array within at least a portion of the spatial region corresponding with said topological mode; and at least one output port optically coupled to one or more of the optical resonators associated with said topological mode, said at least one output port being configured for extracting a portion of light intensity from said laser system. 2. The laser system of claim 1 , wherein said array of optical the elements is configured as a photonic crystal having a band structure associated with photonic states within said photonic crystal, said band structure comprising one or more photonic states crossing a gap between bands of the photonic states; said one or more photonic states crossing said gap correspond with the at least one topological mode within the array. 3. The laser system of claim 1 , wherein said array is a two-dimensional array, said at least one topological mode being associated with at least one edge states travelling along periphery of said array. 4. The laser system of claim 1 , wherein said optical elements are arranged with spatial variation between them providing phase shift to light components coupled between the rows of the array in one direction different with respect to opposite direction. 5. The laser system of claim 1 , wherein coupling between said optical elements of the array is configured such that coupling between optical elements of different rows introduce selected phase shift to light coupling in one direction and different phase shift to light coupling in the opposite direction. 6. The laser system of claim 1 , wherein said optical resonators are ring resonators. 7. The laser system of claim 1 , wherein said optical resonators comprise at least one helical portion. 8. The laser system of claim 1 , where said shifts in location of the optical links vary by predetermined step level between different rows of the array. 9. The laser system of claim 1 , wherein said array has lattice geometry selected from: rectangular, hexagonal, honeycomb or having a triangular lattice of sub-array units where each unit is formed by honeycomb lattice. 10. The laser system of claim 1 , wherein said gain material comprises at least one Nitride compound. 11. The laser system of claim 10 , wherein said Nitride compound comprises at least one Gallium containing layer. 12. The system of claim 1 , wherein said at least one output port comprises at least one optical fiber arranged along a selected and wherein a region of said optical fiber is positioned in close proximity to at least one optical element located at edge of the array to thereby enable out coupling of optical emission from one or more topological modes of the array. 13. A laser system, comprising: an array of optical elements configured as optical resonators comprising optical resonators comprising gain material, the optical elements of the array being optically coupled between them and spatially arranged supporting at least one topological mode associated with certain spatial region of the array, wherein said array is configured as a two-dimensional array, said array comprising a plurality of optical links coupling between adjacent optical resonators, optical links of different rows of the array being shifted with respect to optical links of neighboring rows by a predetermined shift, thereby providing predetermined shift in phase accumulation of light passing through said links in clockwise or counterclockwise directions; a pumping unit configured to provide pumping of a group of the optical elements of the array within at least a portion of the spatial region corresponding with said topological mode; and at least one output port optically coupled to one or more of the optical elements associated with said topological mode, said at least one output ports being configured for extracting a portion of light intensity from said laser system. 14. The laser system of claim 13 , characterized by at least one of the following: said optical resonators are ring resonators; said optical resonators comprise at least one helical portion; said array has lattice geometry selected from: rectangular, hexagonal, honeycomb or having a triangular lattice of sub-array units where each unit is formed by honeycomb lattice; said gain material comprises at least one Nitride compound; said at least one output port comprises at least one optical fiber arranged along a selected and wherein a region of said optical fiber is positioned in close proximity to at least one optical element located at edge of the array to thereby enable out coupling of optical emission from one or more topological modes of the array. 15. A laser system, comprising: an array of optical elements configured as optical resonators comprising optical resonators comprising gain material, the optical elements of the array being optically coupled between them and spatially arranged supporting at least one topological mode associated with certain spatial region of the array, wherein said optical resonators are directly coupled between them, and wherein at least one of internal resonator geometry and coupling between neighboring resonators is varied along the array providing an optical topological mode; a pumping unit configured to provide pumping of a group of the optical elements of the array within at least a portion of the spatial region corresponding with said topological mode; and at least one output port optically coupled to one or more of the optical elements associated with said topological mode, said at least one output ports being configured for extracting a portion of light intensity from said laser system. 16. The laser system of claim 15 , characterized by at least one of the following: said optical resonators are ring resonators; said optical resonators comprise at least one helical portion; said array has lattice geometry selected from: rectangular, hexagonal, honeycomb or having a triangular lattice of sub-array units where each unit is formed by honeycomb lattice; said gain material comprises at least one Nitride compound; said at least one output port comprises at least one optical fiber arranged along a selected and wherein a region of said optical fiber is positioned in close proximity to at least one optical element located at edge of the array to thereby enable out coupling of optical emission from one or more topological modes of the array. 17. A laser system, comprising: an array of optical elements configured as optical resonators comprising optical resonators comprising gain material, the optical elements of the array being optically coupled between them and spatially arranged supporting at least one topological mode associated with certain spatial region of the array, wherein sai