Multi-qubit tunable coupling architecture using fixed-frequency superconducting qubits

What is claimed is: 1. A coupling mechanism comprising: two qubits that are detuned in an idle state such that an interaction between the two qubits is switched off; and a tunable coupling qubit that activates the interaction between the two qubits by modulation of a frequency of the tunable coupling qubit at a difference frequency between the two qubits that is at least 1 GHz larger than an anharmonicity of the two qubits. 2. The coupling mechanism of claim 1 , wherein the tunable coupling qubit capacitively couples the two qubits. 3. The coupling mechanism of claim 1 , wherein the tunable coupling qubit is coupled to the two qubits by two electrodes separated by a superconducting quantum interference device loop having two Josephson junctions. 4. The coupling mechanism of claim 1 , wherein the tunable coupling qubit is coupled to the two qubits by a single electrode with a superconducting quantum interference device loop coupling to ground. 5. The coupling mechanism of claim 1 , wherein the superconducting quantum interference device loop is used to control an inductively-coupled flux bias line positioned such that capacitive coupling to two electrodes of the tunable coupling qubit is symmetric. 6. The coupling mechanism of claim 1 , wherein the exchange-type interaction swaps an excitation between the two qubits. 7. The coupling mechanism of claim 1 , wherein the exchange-type interaction induces a state-dependent phase shift on one of the two qubits. 8. The coupling mechanism of claim 1 , wherein the tunable coupling qubit produces a coupling of the two qubits having a strength dependent upon an amplitude of the modulation frequency and a phase dependent upon a phase of the modulation frequency. 9. The coupling mechanism of claim 1 , wherein the two qubits are transmon type qubits. 10. The coupling mechanism of claim 1 , wherein the two fixed-frequency qubits are initially decoupled. 11. The coupling mechanism of claim 1 , wherein the two fixed-frequency qubits are symmetrically positioned mirror qubits and the tunable coupling qubit is positioned between the two qubits. 12. The coupling mechanism of claim 1 , wherein the two qubits are fixed-frequency qubits. 13. A method of activating a coupling mechanism comprising: positioning a tunable coupling qubit between two qubits; and modulating a frequency of the tunable coupling qubit at a difference frequency between the two qubits that is at least 1 GHz larger than an anharmonicity of the two qubits. 14. The method of claim 13 , wherein the tunable coupling qubit is modulated at a difference frequency of the two qubits. 15. The method of claim 13 , wherein the tunable coupling qubit is coupled to the two qubits by two electrodes separated by a superconducting quantum interference device loop having two Josephson junctions. 16. The method of claim 13 , further comprising using the coupling mechanism as a basis of a universal quantum computer that uses error correction. 17. The method of claim 13 , further comprising using the coupling mechanism as a platform for quantum simulation of systems interacting based on a lattice of qubits connected via coupling elements mediating interactions between nearest neighbor pairs of qubits. 18. The method of claim 17 , wherein the systems are interacting via a Heisenberg XYZ interaction. 19. The method of claim 13 , wherein one of the two qubits is a low-coherence transmon, the method further comprises swapping excitations to the low-coherence transmon such that initial thermal excitations of the low-coherence transmon are transferred into a surrounding environment to cool the qubit. 20. The method of claim 13 , wherein one of the two qubits is in an excited state, the method further comprises resetting the one of the two qubits to its ground state. 21. A square lattice comprising: a plurality of unit cells, each unit cell comprising: two or more qubits, wherein a pair of qubits of the two or more qubits are detuned in an idle state such that an interaction between the pair of qubits is switched off; and a tunable coupling qubit that activates the interaction between a pair of qubits of the two or more qubits by modulation of a frequency of the tunable coupling qubit at a difference frequency between the pair of qubits that is at least 1 GHz larger than an anharmonicity of the two qubits. 22. A quantum gate comprising: two superconducting qubits that are detuned in an idle state such that an interaction between the two superconducting is switched off; and a tunable coupling qubit that activates an interaction between the two superconducting qubits by modulation of a frequency of the tunable coupling qubit at a difference frequency between the two superconducting qubits that is at least 1 GHz larger than an anharmonicity of the two qubits.