Pure dephasing in flux qubits due to flux noise with spectral density scaling as 1/ fα

Abstract

For many types of superconducting qubits, magnetic flux noise is a source of pure dephasing. Measurements on a representative dc superconducting quantum interference device (SQUID) over a range of temperatures show that S(f) = A2/(f/1 Hz)α, where S is the flux noise spectral density, A is of the order of 1 μ0 \, Hz-1/2 and 0.61 ≤ α ≤ 0.95; 0 is the flux quantum. For a qubit with an energy level splitting linearly coupled to the applied flux, calculations of the dependence of the pure dephasing time τφ of Ramsey and echo pulse sequences on α for fixed A show that τφ decreases rapidly as α is reduced. We find that τφ is relatively insensitive to the noise bandwidth, f1 ≤ f ≤ f2, for all α provided the ultraviolet cutoff frequency f2 > 1/τφ. We calculate the ratio τφ,E / τφ,R of the echo (E) and Ramsey (R) sequences, and the dependence of the decay function on α and f2. We investigate the case in which S(f0) is fixed at the "pivot frequency" f0 ≠ 1 Hz while α is varied, and find that the choice of f0 can greatly influence the sensitivity of τφ,E and τφ,R to the value of α. Finally, we present calculated values of τφ in a qubit corresponding to the values of A and α measured in our SQUID.