Microwave circulator

The invention claimed is: 1. A microwave circulator including an integrated circuit having: a) a number of ports; b) multiple respective ring segments coupled to each port to allow microwave frequency signals to be transferred between the respective port and the respective ring segments, the multiple ring segments being arranged to define multiple parallel circulator rings; and, c) at least one superconducting tunnel junction interconnecting each pair of adjacent ring segments in a circulator ring, wherein the tunnel junctions are configured so that when a bias is applied to the tunnel junctions, signals undergo a phase shift as they traverse the tunnel junctions between ring segments, thereby propagating signals to an adjacent port in a propagation direction, and wherein the circulator rings propagate signals having different frequency ranges. 2. A microwave circulator according to claim 1 , wherein the circulator includes: a) at least two circulator rings; b) at least three circulator rings; c) at least five circulator rings; or, d) at least ten circulator rings. 3. A microwave circulator according to claim 1 , wherein the propagation direction is dependent on at least one of a magnitude and polarity of the bias. 4. A microwave circulator according to claim 1 , wherein the bias includes: a) a central bias applied to all of the tunnel junctions; and, b) a segment bias applied to each ring segment. 5. A microwave circulator according to claim 1 , wherein the bias includes at least one of a magnetic or electric field. 6. A microwave circulator according to claim 1 , wherein each port is coupled to at least one of the multiple respective ring segments at least one of: a) capacitively; b) inductively; and, c) using a superconducting tunnel junction. 7. A microwave circulator according to claim 6 , wherein each port is coupled to a first ring segment, and wherein the other ring segments are coupled to the first ring segment at least one of: a) capacitively; b) inductively; and, c) using a superconducting tunnel junction. 8. A microwave circulator according claim 1 , wherein each circulator ring has at least one of: a) a different configuration; b) a different configuration of tunnel junctions; c) tunnel junctions having different properties; and, d) different biases. 9. A microwave circulator according to claim 1 , wherein the circulator rings are at least partially coupled. 10. A microwave circulator according to claim 1 , wherein the tunnel junctions provide at least one of: a) a specific inductance; and, b) a specific capacitance. 11. A microwave circulator according to claim 1 , wherein the tunnel junctions are at least one of: a) Josephson junctions; and, b) quantum phase slip junctions. 12. A microwave circulator according to claim 1 , wherein: a) the tunnel junctions are Josephson junctions; b) the ports and ring segments are capacitively coupled; c) the tunnel junctions introduce a specific capacitance between ring segments; and, d) the bias includes a magnetic field bias. 13. A microwave circulator according to claim 1 , wherein the tunnel junctions are Josephson junctions including superconducting electrodes separated by a tunnelling barrier, and wherein the junction has a cross sectional area of at least one of: a) at least 20 nm 2 ; b) less than 500 nm 2 ; c) less than 150 μm 2 ; and, d) about 100 nm 2 . 14. A microwave circulator according to claim 1 , wherein the tunnel junctions are Josephson junctions and the current density is at least one of: a) between 20 and 200 A/m 2 ; and, b) between 0.2×10 8 and 4×10 8 A/m 2 . 15. A microwave circulator according to claim 13 , wherein the integrated circuit includes: a) a substrate; b) a first superconducting film provided on the substrate that is to form a lower electrode of each Josephson junction; c) an insulating layer provided on at least part of a first conductive film that forms the Josephson tunnelling barrier of the Josephson junctions; and, d) a second superconducting film spanning the insulating layer on adjacent lower electrodes to form counter electrodes of each Josephson junction. 16. A microwave circulator according to claim 15 , wherein at least one of: a) the superconducting films are made of at least one of: i) niobium; and, ii) aluminium; and, b) the insulating layer is made of aluminium oxide. 17. A microwave circulator according to claim 12 , wherein the bias includes: a) a central bias generated by applying a magnetic field to the ring; and, b) a segment bias generated by applying a bias voltage to each ring segment. 18. A microwave circulator according to claim 1 , wherein: a) the tunnel junctions are quantum phase slip junctions; b) the ports and ring segments are inductively coupled; c) the tunnel junctions introduce a specific inductance between ring segments; and, d) the bias includes a charge bias. 19. A microwave circulator according to claim 1 , wherein the tunnel junctions are quantum phase slip junctions including nanoscale width conductors extending radially to a central island. 20. A microwave circulator according to claim 19 , wherein the nanoscale width conductors include a section having a width of at least one of: a) greater than 10 nm; b) less than 100 nm; and, c) about 40 nm. 21. A microwave circulator according to claim 18 , wherein the bias includes: a) a central charge bias generated by applying a bias voltage to the central island; and, b) a segment bias generated by applying a bias magnetic field to each ring segment. 22. A microwave circulator according to claim 1 , wherein the tunnel junctions are quantum phase slip junctions including Josephson junctions in series with one or more inductors. 23. A microwave circulator according to claim 1 , wherein the circulator includes at least three ports and three ring segments. 24. A microwave circulator according to claim 1 , wherein a plurality of superconducting tunnel junctions interconnect each pair of adjacent ring segments in at least one circulator ring, wherein the plurality of tunnel junctions are configured so that when a bias is applied to the tunnel junctions, signals undergo a phase shift as they traverse the tunnel junctions between ring segments, thereby propagating signals to an adjacent port in a propagation direction. 25. A microwave circulator according to claim 24 , wherein the plurality of superconducting tunnel junctions are provided in at least one of series and parallel between adjacent ring segments. 26. A microwave circulator according to claim 24 , wherein the phase shift is a sum of phase shifts introduced by each of the plurality of tunnel junctions. 27. A microwave circulator according to claim 24 , wherein the plurality of tunnel junctions includes a sufficient number of tunnel junctions so that the response of each tunnel junction is substantially linear over at least one of: a) a defined signal frequency range; and, b) a defined signal power range. 28. A microwave circulator according to claim 24 , wherein each plurality of tunnel junctions includes: a) at least two tunnel junctions; b) at least ten tunnel junctions; c) at least fifty tunnel junctions; d) at least one hundred tunnel junctions; or, e) several hundred tunnel junctions. 29. A microwave