Optimal thickness of rectangular superconducting microtraps for cold atomic gases

Placing an ensemble of \(10^6\) ultracold atoms in the near field of a superconducting coplanar waveguide resonator (CPWR) with \(Q \sim 10^6\) one can achieve strong coupling between a single microwave photon in the CPWR and a collective hyperfine qubit state in the ensemble with \(g_\textit{eff} / {2 \pi} \sim 40\) kHz larger than the cavity line width of \({\kappa}/{2 \pi} \sim 7\) kHz. Integrated on an atomchip such a system constitutes a hybrid quantum device, which also can be used to interconnect solid-state and atomic qubits, to study and control atomic motion via the microwave field, observe microwave super-radiance, build an integrated micro maser or even cool the resonator field via the atoms.

We have trapped rubidium atoms in the magnetic field produced by a superconducting atom chip operated at liquid helium temperatures. Up to 8.2x10(5) atoms are held in a Ioffe-Pritchard trap at a distance of 440 microm from the chip surface, with a temperature of 40 microK. The trap lifetime reaches 115 s at low atomic densities. These results open the way to the exploration of atom-surface interactions and coherent atomic transport in a superconducting environment, whose properties are radically different from normal metals at room temperature.