Dipole element for superconducting circuits

The invention claimed is: 1. An inductive dipole element for a superconducting microwave quantum circuit, the dipole element comprising: a DC-SQUID formed by first and second Josephson junctions shunted by an inductance, wherein the first and second Josephson junctions have equal energy, wherein the first and second Josephson junctions and the inductance are arranged such that each of the junctions respectively forms first and second superconducting loops with the inductance, the first and second superconducting loops being asymmetrically threaded with independently controlled external magnetic DC fluxes φ ext1 and φ ext2 , respectively, such that φ ext1 =π and φ ext2 =0, and wherein parametric pumping is enabled by modulating a total flux φ Σ =φ ext,1 +φ ext,2 threading the dipole element, thereby allowing even-wave mixing between modes that participate in the dipole element with no Kerr-like interactions. 2. The dipole element according to claim 1 , wherein the parametric pumping is further enabled by also modulating a differential flux φ Δ =φ ext,1 −φ ext,2 with an appropriate modulation phase and amplitude. 3. The dipole element according to claim 1 , wherein the external magnetic DC fluxes φ ext,1 and φ ext,2 are applied via superconducting lines that are adjacent to the superconducting loops, in which both a DC and an AC current circulate. 4. The dipole element according to claim 3 , wherein the superconducting lines are directly connected to wires of the loops. 5. The dipole element according to claim 3 , wherein the superconducting lines are arranged such that one input current I Σ biases the total flux in the dipole element, φ Σ =φ ext,1 +φ ext, 2 , and another input current I Δ biases the differential flux of the dipole element, φ Δ =φ ext,1 −φ ext2 , and wherein the parametric pumping is delivered by the oscillating magnetic flux generated by the oscillating component of I Σ . 6. The dipole element according to claim 1 , wherein the inductance comprises a superconducting wire made of plain or granular superconducting material. 7. The dipole element according to claim 1 , wherein the inductance comprises a chain of Josephson junctions connected in series with each other. 8. An inductive dipole element for a superconducting microwave quantum circuit, the inductive dipole element comprising: a first DC-SQUID, formed by a Josephson junction and a second DC-SQUID, the Josephson junction and the second DC-SQUID arranged in parallel so as to form a loop that is shunted by an inductance, wherein the Josephson junction and the second DC-SQUID have equal energy, wherein the Josephson junction, the second DC-SQUID, and the inductance are arranged such that the Josephson junction and the second DC-SQUID respectively form with the inductance a first superconducting loop and a second superconducting loop, the first and second superconducting loops being asymmetrically threaded with external magnetic DC fluxes φ ext1 and φ ext2 , respectively, such that φ ext1 =π and φ ext2 =0, and wherein parametric pumping is enabled by modulating a total flux φ Σ =φ ext1 +φ ext2 threading the inductive dipole element, thereby allowing even-wave mixing between modes that participate in the inductive dipole element with no Kerr-like interactions. 9. A superconducting microwave quantum circuit, comprising a dipole element according to claim 1 , the dipole element being capacitively shunted to form a non-linear resonator coupled to a linear resonator, wherein the non-linear interaction provided by the parametrically pumped dipole element causes a two-to-one photon exchange between the linear resonator and the non-linear resonator.