Engineering Dynamical Sweet Spots to Protect Qubits from 1/f Noise

Protecting superconducting qubits from low-frequency noise is important for advancing superconducting quantum computation. We present a protocol for engineering dynamical sweet spots protecting against 1/f noise, using a periodic drive. The position and strength of dynamical sweet spots can be obtained analytically in the framework of Floquet theory. For the example of fluxonium biased slightly away from half a flux quantum, we predict an improvement in pure-dephasing time from less than 1 μs to over 1 ms. Using the Floquet eigenstates as the computational basis, we show that high-fidelity single-qubit gates can be implemented at dynamical sweet spots. We further confirm that qubit readout can be performed by adiabatically mapping the qubit's Floquet states to the static qubit states, and subsequently employing standard measurement techniques.