Josephson Junction Materials Research Using Phase Qubits

 

R.W. Simmonds, D.A. Hite, R. McDermott, M. Steffen, K.B. Cooper, K.M. Lang, John M. Martinis, D.P. Pappas

To appear in "Quantum Computation: solid state systems" by P. Delsing, C. Granata, Y. Pashkin, B. Ruggiero and P.

Silvestrini, December, 2004

At present, the performance of superconducting qubits is limited by decoherence. Strong decoherence of phase qubits is associated with spurious microwave resonators residing within the Josephson junction tunnel barrier [1]. In this work, we investigate three different fabrication techniques for producing tunnel junctions that vary the properties of the superconductor-insulator interface. Through experimental measurements, we characterize the junction and corresponding qubit quality. We find that there is a strong correlation between the morphology of oxidized base electrodes and the lowering  of subgap currents in the junction I-V characteristic, while there is no noticeable improvement in the performance of fabricated qubits. Thus, “traditional” indicators of junction performance may not be enough to determine qubit performance. However, truly crystalline insulating barriers may be the key to improving Josephson junction based qubits.

 

 

[1] R.W. Simmonds, K.M. Lang, D.A. Hite, D.P. Pappas, John M. Martinis, Decoherence in Josephson Phase Qubits from Junction Resonators, Phys. Rev. Lett. 93, 077003 (2004).