Intrinsic leakage of the Josephson flux qubit and breakdown of the two-level approximation for strong driving

ALEJANDRO FERRÓN; DANIEL DOMINGUEZ

PHYSICAL REVIEW B

AMER PHYSICAL SOC

Año: 2010 vol. 81 p. 104505 - 104505

1098-0121

Solid-state devices for quantum-bit computation (qubits) are not perfect isolated two-level systems since additional higher energy levels always exist. One example is the Josephson flux qubit, which consists on a mesoscopic superconducting quantum interference device loop with three Josephson junctions operated at or near a magnetic flux of half quantum. We study intrinsic leakage effects, i.e., direct transitions from the allowed qubit states to higher excited states of the system during the application of pulses for quantum computation operations. The system is started in the ground state and rf-magnetic field pulses are applied at the qubit resonant frequency with pulse intensity fp. A perturbative calculation of the average leakage for small fp is performed for this case, obtaining that the leakage is quadratic in fp, and that it depends mainly on the matrix elements of the supercurrent. Numerical simulations of the time-dependent Schrödinger equation corresponding to the full Hamiltonian of this device were also performed. From the simulations we obtain the value of fp above which the two-level approximation breaks down, and we estimate the maximum Rabi frequency that can be achieved. We study the leakage as a function of the ratio α among the Josephson energies of the junctions of the device, obtaining the best value for minimum leakage (α≈0.85). The effects of flux noise on the leakage are also discussed.