Mode matched Y-junction

I claim: 1. A waveguide Y-splitter comprising: an input port for launching an input beam of light; an input waveguide including a longitudinal axis, capable of providing adiabatic expansion of the input beam of light from the input port to an output end, which has a width that supports a fundamental mode and a second order mode; first and second output waveguides extending from the output end of the input waveguide on either side of the longitudinal axis and separated by a gap, wherein each of the first and second output waveguides includes an initial section having an inner wall, defining the gap, substantially parallel to the longitudinal axis, and wherein the initial sections and the gap are capable of supporting a super mode of the incoming beam of light, which spans the first and second output waveguides and the gap; and a mode-matching junction between the input waveguide and the first and second output waveguides for splitting the input beam of light, capable of propagating the fundamental mode of the incoming light to a fundamental super mode; wherein the initial section of the first output waveguide comprises a constant width; and wherein the initial section of the second output waveguide comprises a width expanding in order to create an imbalance in the power distribution at the output waveguides. 2. The Y-splitter according to claim 1 , wherein the width of the input waveguide expands adiabatically from a width supporting single mode propagation of the input beam of light to the output end. 3. The Y-splitter according to claim 1 , wherein the initial sections extend at least 1 μm from the input waveguide at a constant width and a constant gap therebetween. 4. The Y-splitter according to claim 1 , wherein the mode matching junction includes a discontinuity in the input waveguide to provide mode matching between the input waveguide and the first and second output waveguides. 5. The Y-splitter according to claim 4 , wherein the output end of the input waveguide is wider than a combined width of the gap and the first and second output waveguides resulting in the discontinuity. 6. The Y-splitter according to claim 5 , wherein the discontinuity comprises shoulder surfaces perpendicular to the longitudinal axis adjacent outer sides of the first and second output waveguides. 7. The Y-splitter according to claim 6 , wherein the shoulder surfaces are wider than the gap, and not as wide as the first output waveguide. 8. The Y-splitter according to claim 6 , wherein a width at the output end of the input waveguide is about twice as wide as a combined width of the first and second output waveguides. 9. The Y-splitter according to claim 4 , wherein the mode-matching junction further comprises a subwavelength grating in the gap. 10. The Y-splitter according to claim 1 , wherein the subwavelength grating start with a high fill ratio in the gap and adiabatically taper to a low fill ratio. 11. A waveguide Y-splitter comprising: an input port for launching an input beam of light; an input waveguide including a longitudinal axis, capable of providing adiabatic expansion of the input beam of light from the input port to an output end, which has a width that supports a fundamental mode and a second order mode; first and second output waveguides extending from the output end of the input waveguide on either side of the longitudinal axis and separated by a gap, wherein each of the first and second output waveguides includes an initial section having an inner wall, defining the gap, substantially parallel to the longitudinal axis, and wherein the initial sections and the gap are capable of supporting a super mode of the incoming beam of light, which spans the first and second output waveguides and the gap; and a mode-matching junction between the input waveguide and the first and second output waveguides for splitting the input beam of light, capable of propagating the fundamental mode of the incoming light to a fundamental super mode; wherein the mode-matching junction further comprises a subwavelength grating in the gap. 12. The Y-splitter according to claim 11 , wherein the subwavelength grating start with a high fill ratio in the gap and adiabatically taper to a low fill ratio. 13. The Y-splitter according to claim 1 , wherein each of the first and second output waveguides also includes a mode splitting section extending from the initial section at an acute angle to the longitudinal axis. 14. The Y-splitter according to claim 13 , wherein the acute angle is between 3° and 15°. 15. The Y-splitter according to claim 1 , wherein each of the first and second output waveguides further comprises an expansion section extending from the mode splitting section, each expansion section expanding a width of each of the first and second output waveguides. 16. The Y-splitter according to claim 15 , wherein an inner wall of each of the expansion sections is at the acute angle to the longitudinal axis. 17. The Y-splitter according to claim 11 , wherein the initial section of the first output waveguide comprises a constant width; and wherein the initial section of the second output waveguide comprises a width expanding in order to create an imbalance in the power distribution at the output waveguides. 18. The Y-splitter according to claim 1 , wherein the initial sections extend at least 5 μm from the input waveguide with a constant gap therebetween. 19. The Y-splitter according to claim 18 , wherein the first output waveguide further comprises a final expansion section extending from the mode splitting section, the final expansion section expanding a width of the first output waveguide. 20. The Y-splitter according to claim 19 , wherein an inner wall of the final expansion section is at the acute angle to the longitudinal axis.